CN114358591B - A method and system for engineering construction management of engineering objects - Google Patents

Abstract

The present invention relates to an engineering construction management system and method for engineering objects, wherein each attribute parameter of the same engineering object establishes an association relationship with each management module; in response to parameter change information of a pre-specified attribute of at least one engineering object issued by a design management module, a procurement management module and/or a construction management module associated with the pre-specified attribute adjusts related procurement parameter information and/or construction parameter information based on the parameter change information and issues at least one reminder message; in response to parameter change information of a pre-specified attribute of at least one engineering object issued by the procurement management module, a construction management module associated with the pre-specified attribute compares the parameter change information of the engineering object with necessary engineering objects involved within a preset time range, and when the engineering object is a necessary engineering object, the construction management module issues at least one reminder message.

Description

Engineering construction management method and system for engineering objects

Technical Field

The invention relates to the technical field of engineering management, in particular to an engineering construction management method and system of an engineering object.

Background

Along with the industrial promotion, the project of engineering construction is gradually increased in recent years, the project of engineering construction faces the urgent progress, the multiple pressures of the increasing cost and quality safety problem, but the traditional project management system only realizes that the work of off-line paper is carried to the line for execution, the participation personnel are few, the whole project chain cannot be driven by the original data, the project construction data are mutually split, the data are repeatedly recorded, the data query is difficult, and the project management system is repeatedly constructed due to the diversity of the project, so that huge pressure is brought to the server, the performance and capacity of the server are required to be improved frequently, and the social resource is wasted.

For example, patent document CN105354652 a discloses an intelligent management system for engineering construction projects, comprising a server and a plurality of clients; the server is stored with an engineering model, and the client is provided with a cost management module and a progress management module; the engineering model comprises an engineering module and a covering layer; the project module is a display module of a sub project displayed in the project construction project; the engineering module comprises a plurality of sub-modules, wherein each sub-module is a module diagram formed by singly or in combination of a graph or a table which is manufactured according to the construction position and the stress characteristic of a construction diagram in an engineering construction project and by combining a construction method and construction capacity; the covering layer is covered on the engineering module or the sub-module, and the shape, the graph and the size of the covering layer are consistent with those of the engineering module or the sub-module, so that the information display and the management of the working content of the structural part of the corresponding sub-engineering of the engineering module or the sub-module are carried out; the cost management module is used for calling the engineering model on the server, displaying cost information of the structural part corresponding to the project on the engineering model and managing the cost on the engineering model; the progress management module is used for calling the engineering model on the server, displaying the progress information of the structural part corresponding to the project on the engineering model and carrying out progress management on the engineering model. However, the data searching main line is disordered, and meanwhile, the data of the whole engineering construction life cycle in design, purchase, construction, debugging and finishing can not be comprehensively managed based on engineering objects, and the data can not be used for project management activities such as progress, cost, quality and the like, and can ensure a single data source.

Furthermore, there are differences in one aspect due to understanding to those skilled in the art; on the other hand, since the applicant has studied a lot of documents and patents while making the present invention, the text is not limited to details and contents of all but it is by no means the present invention does not have these prior art features, but the present invention has all the prior art features, and the applicant remains in the background art to which the right of the related prior art is added.

Disclosure of Invention

In the engineering construction management system in the prior art, attribute data stored by each management module belongs to static data, namely data which cannot be changed. This makes it necessary for the data of each management module to be updated manually or for the same attribute parameters in each management module list to be stored repeatedly, and synchronization update cannot be performed in time. In the engineering construction management, the engineering progress of each engineering object is not uniform, and the information of each management module cannot be updated in time under the condition of no manual monitoring progress, so that the information progress of each management module is different.

Based on the defects of the prior art, the invention hopes to provide a management system which can automatically update the data list of each management module, automatically update the progress state and actively remind the engineering management progress through the terminal so as to realize the automatic management of the management system.

Aiming at the defects of the prior art, the invention provides an engineering construction management system of an engineering object, wherein each attribute parameter of the same engineering object and each management module establish an association relation; the management module at least comprises a design management module, a purchase management module and a construction management module which are respectively connected with the server in a wired or wireless mode; in response to parameter change information of a pre-specified attribute of at least one engineering object sent by the design management module, the purchasing management module and/or the construction management module associated with the pre-specified attribute adjusts related purchasing parameter information and/or construction parameter information based on the parameter change information and sends at least one reminding information.

In response to parameter change information of a pre-specified attribute of at least one engineering object sent by the purchase management module, a construction management module associated with the pre-specified attribute compares the parameter change information of the engineering object with necessary engineering objects related in a preset time range, and sends at least one reminding information under the condition that the engineering object belongs to the necessary engineering object.

According to the invention, through monitoring the pre-designated attribute parameter change information among the management modules, the management modules related to the attribute parameters can be synchronously changed, so that the adjustment of each other is automatically realized.

Preferably, the system further comprises a debugging management module, the construction management module determines the progress of the engineering object based on image information acquired by a plurality of sensors, the debugging management module selects debugging content and performs automatic debugging based on attribute information of the engineering object in response to a signal of an installation completion state sent by the construction management module, and the construction management module feeds a debugging result back to the construction management module. The engineering objects are monitored and automatically debugged through the image information, so that the delay time for judgment and management of staff is reduced, and engineering management can be automatically performed.

Preferably, the system further comprises a progress management module, wherein the progress management module adjusts attribute information associated with the construction management module and/or the debugging management module based on the attribute parameter information of the engineering object fed back by the design management module, the purchasing management module, the construction management module and/or the debugging management module, so that the time interval between the purchasing progress, the construction progress and the debugging progress of the engineering object is within a preset time range. When the time intervals among the purchasing progress, the construction progress and the debugging progress are not in the preset time range, the method and the device can coordinate rapidly based on the reminding information, so that the defect that each progress of the project is not coordinated due to the fact that a single management module changes the attribute parameters is avoided. The invention can quickly find out the uncoordinated problem and promote the staff to carry out coordination management.

Preferably, the system further comprises a cost management module, wherein the cost management module updates the estimated information of the engineering cost based on the purchasing information of a plurality of engineering objects and/or the change of the engineering progress, wherein the cost management module updates the estimated information of the engineering cost when the purchasing information and/or the change of the engineering progress and/or the accumulated change reach a limit value, and maintains the current estimated information of the engineering cost when the purchasing information and/or the change of the engineering progress and/or the accumulated change do not reach the limit value. The engineering cost evaluation is complex, the purchasing cost of a plurality of engineering objects is dynamic at the same time, and the latest cost evaluation information is difficult to evaluate accurately. Therefore, the invention evaluates based on the dynamic attribute parameters and effectively reminds based on the limiting values, thereby not only reducing the phenomenon that the staff frequently checks the cost management module, but also avoiding the influence of the attribute parameters influencing the cost evaluation and the key change of the total cost, and being beneficial to the staff to take management measures in time to coordinate the evaluation of the total cost.

Preferably, the system further comprises a quality management module and a handover management module, wherein the quality management module sends a tracking instruction to the progress management module based on unqualified state information of the engineering object, and when the latest debugging result of the engineering object is sent to the progress management module by the debugging management module, the progress management module responds to the tracking instruction and sends quality acceptance reminding information; or the quality management module sends a handover instruction to the handover management module based on the qualified state information of the engineering object, and the handover management module responds to the handover instruction and extracts attribute parameters of the engineering object to generate a handover list. By the arrangement, quality management can be automatically performed based on the tracking instruction, so that the time delay of the cooperation time of each department is reduced, and engineering management can be effectively performed.

Preferably, the system further comprises a human resource management module, wherein the human resource management module is used for sending attribute information of the engineering object to the schedulable personnel terminal based on the historical human resource information corresponding to the engineering preparation progress in response to the engineering preparation progress information sent by the progress management module based on the preset engineering progress node. By the arrangement, the human resource management can automatically distribute work details and work progress to constructors, and timely master the allocation situation of the constructors, so that the links of manual scheduling of the constructors are reduced, whether the human resources are enough to evaluate is more accurate, and the working personnel can work clearly for themselves.

Preferably, the human resource management module updates the constructor corresponding to the handover information to the person to be scheduled based on the handover information transmitted by the handover management module. So set up, avoided the idle of schedulable personnel, practiced thrift the human cost promptly.

Preferably, the attribute parameters of the engineering object are dynamic attribute parameters updatable by at least one management module, the attribute parameters are associated with the engineering object, the attribute parameter category is associated with at least one management module, and the management module extracts the dynamic attribute parameters associated with the engineering object based on a preset attribute list and forms dynamic management data of the engineering object. The dynamic attribute parameters are set, so that each management module can synchronously change based on the change of the attribute parameters, the uncoordinated problem of each management module can be quickly found, the problem finding time is saved, and engineering management can be quickly promoted.

The invention also provides an engineering construction management method of the engineering object, which at least comprises the following steps: establishing association relation between each attribute parameter of the same engineering object and each management module; responding to parameter change information of pre-designated attributes of at least one engineering object sent by a design management module, and adjusting related purchase parameter information and/or construction parameter information and sending at least one reminding information by a purchase management module and/or a construction management module associated with the pre-designated attributes based on the parameter change information; in response to parameter change information of a pre-specified attribute of at least one engineering object sent by the purchase management module, a construction management module associated with the pre-specified attribute compares the parameter change information of the engineering object with necessary engineering objects related in a preset time range, and sends at least one reminding information under the condition that the engineering object belongs to the necessary engineering object.

Preferably, the method further comprises: the construction management module determines the progress of the engineering object based on image information acquired by a plurality of sensors, responds to a signal of the installation completion state sent by the construction management module, the debugging management module selects debugging content based on attribute information of the engineering object and carries out automatic debugging, and the construction management module feeds back a debugging result to the construction management module.

Drawings

FIG. 1 is a schematic diagram of a preferred information structure combination of an engineering construction management system for an engineering object according to the present invention;

Fig. 2 is a simplified module connection relationship diagram of a preferred information interaction of the engineering construction management system of the engineering object provided by the invention.

List of reference numerals

1: A factory structure; 2: transmitting information; 3: a classification database; 10: a plant model; 20: a device model; 30: a system model; 40: a partition model; 50: an engineering object; 60: document information; 70: a factory object class; 80: a professional document class; 101: a design management module; 102: a purchase management module; 103: a construction management module; 104: a debugging management module; 105: a progress management module; 106: a cost management module; 107: a quality management module; 108: a handover management module; 109: a human resource management module; 110: a document management module; 200: a GIS management module; 501: numbering; 502: specification information; 503: space coordinates; 504: purchasing information; 505: unit price information; 506: data information; 507: construction progress information; 508: acceptance information; 509: debugging information; 51O: and handover information.

Detailed Description

The following detailed description refers to the accompanying drawings.

The invention provides an engineering construction management system and an engineering construction management system for an engineering object, and also provides a system and a method for scheduling attribute parameters of the engineering object, and further provides a system and a method for monitoring engineering progress.

In contrast to the prior art, the respective property parameters of the engineering object of the invention are dynamic property parameters that are updatable by at least one management module. The property parameters are to be associated with the engineering object and the property parameter category is associated with at least one management module. As shown in fig. 1, the attribute parameters of the engineering object are stored in association with the engineering object as an association core. Wherein, the attribute parameter establishes an association relation with the corresponding management module. Preferably, the attribute parameters belonging to the same engineering object have a time attribute, and change information is stored according to time.

As shown in fig. 1, the dynamic attribute parameters of the engineering object 50 include at least a number 501, specification information 502, space coordinates 503, purchase information 504, unit price information 505, material information 506, construction progress information 507, acceptance information 508, debug information 509, and handover information 510.

When any management module needs to check or call the attribute parameters of a certain engineering object, the latest parameters of a certain attribute of the engineering object can be directly obtained. I.e. the attribute parameters within the list of management modules are not a list where conventional numbers do not change. The attribute parameters of the engineering objects displayed by the management module are dynamically changed based on the change of the attribute parameters in the database. Preferably, the change information of the attribute parameter has a time attribute and is stored with time as the associated information. When the attribute information within the list is selected, attribute parameters at different times can be displayed based on the selection instruction. For example, the unit price of the engineering object is changed twice, and if not selected, the engineering object is managed with the latest unit price. When the user selects the history unit price by the mouse, the attribute field of the unit price displays two unit prices having time information.

When a certain attribute parameter changes, the management module associated with the attribute parameter monitors the attribute parameter change and sends out attribute change reminding information. In the invention, the management module can judge whether to send out the reminding information based on the pre-designated attribute parameter variation amplitude. For example, when the pre-specified attribute parameter changes exceed the limit value, the management module sends out the reminding information, otherwise, the management module does not send out the reminding information. Each management module can be provided in the terminal device. The terminal device is, for example, a computer, a mobile phone, a tablet computer, a portable smart device, etc. The portable smart device is, for example, a smart watch, smart bracelet, smart glasses, virtual device, VR device, etc.

Preferably, the properties of the engineering object of the present invention have class definitions and class hierarchies. The class definition includes various classes with inheritance relationships. The primary class comprises equipment, pipelines, rooms, electricity, meters and the like, and the secondary class, the tertiary class and the like are expanded for the specific primary class until the clustering and the difference of objects required by engineering can be completely described. The invention provides the visual class definition and inheritance relationship, which can be completed by service personnel without intervention of developers, and realizes the visual definition of the system engineering object class.

The attribute definition of the engineering object comprises the type of the configuration data element, and the attribute of the visual field can comprehensively manage the field of the whole system, so that the system resource is saved. The attribute parameters include fields: numerical type parameter text/number/currency, etc., select type parameter manual edit/single/multiple/drop-down menu, etc., display type parameter decimal number/percentage, etc., other special parameter data association/unique identification/sequence identification, etc., and give attribute identification such as: temperature, pressure, length, etc.

The attribute configuration of the engineering object is as follows: the method comprises the steps of configuring attribute information of objects according to different engineering object classes, wherein the attributes of the objects are derived from attribute definitions, and managing the objects according to attribute group according to different attributes so as to solve the problem that the attributes are too many to be effectively managed.

Compared with the prior art, the engineering object attribute information storage and at least one library are provided with the information change monitoring module. The information change monitoring module is used for monitoring the change of the attribute parameters and sending and displaying the latest attribute parameters to the display interface of the management module. Because of the too many attribute parameters, the variation of some attribute parameters is not of interest. If each attribute change sends reminding information to the management module, the management module can continuously receive the reminding information, and too much reminding information forms interference, so that the effect of effective reminding is lost. Based on the defects, the information change monitoring module can also send out reminding information based on the attribute parameters and the changes thereof pre-designated by the management module.

For example, for a certain attribute parameter of the engineering object, the management module pre-specifies a change limit value of the attribute parameter. When the change increment of the attribute parameter reaches the change limit value, the information change monitoring module sends reminding information to the management module. The management module judges whether to send out the reminding information again through information evaluation.

The change limit may be a custom unit amount or an incremental magnitude. For example, when the custom unit amount is 1, which means that the attribute parameter increases by 1 or decreases by 1, the information change monitoring module sends the reminding information to the management module with the unit amount. When the increment amplitude is 2%, and the increment amplitude indicates that each time the attribute parameter is increased by 2% of the current quantity or reduced by 2% of the current quantity, the information change monitoring module sends reminding information to the management module with the set unit quantity. The information change monitoring module sends reminding information to the corresponding management module when the change of the pre-designated attribute parameters reaches the preset unit quantity.

Preferably, when the time when the variation of the attribute parameter reaches the variation limit value has a shortened trend, the management module increases the frequency of information reminding by reducing the variation limit value, so as to avoid missing the influence caused by variation of the attribute parameter of a certain necessary engineering object and avoid the defect of causing engineering delay. For example, the change in the estimated total budget of an engineering is the primary monitoring content of the cost management module. When the total budget of the cost assessment varies greatly, it obviously leads to insufficient expenditure of the project, even making the project eventually unable to finish. For example, an engineering project is made up of sub-projects of several engineering stages. Assume that the limit of variation of the cost estimate for a sub-project is preset to be one hundred thousand. When the cost assessment relating to the sub-project grows for the first time to seven days, the cost management module issues a reminder and records a first time period corresponding to the change limit. When the cost evaluation of the sub-engineering increases for the second time to reach one hundred thousand for five days, the time to reach the change limit is significantly shortened. The cost management module automatically reduces the change limit value of the cost evaluation of the sub-engineering to be fifty thousand, which is favorable for further monitoring the change of the cost evaluation of the sub-engineering, avoids missing the change of the cost of the sub-engineering and does not cause higher frequency of the reminding information, thereby improving the effective rate of the reminding information. Compared with the prior art that the cost change is monitored through the preset time period, so that a certain cost evaluation value is missed to cause the defect of insufficient engineering expense, the cost management module automatically updates the change limit according to the numerical value change of the monitored cost evaluation, and shortens the monitoring period at the same time, so that key numerical values of the cost evaluation are not missed, and the probability of the phenomenon of insufficient expense is obviously reduced.

When the staff of the cost management module confirms that the current cost needs to be reduced, the cost management module is operated to send information of cost reduction information to the purchase management module, the design management module and the human resource management module related to the cost.

Similarly, when the time when the variation of the attribute parameter reaches the variation limit value has a shortened trend, other management modules pay attention to the variation of the important attribute parameter in a mode of reducing the variation limit value, so that the effectiveness of information reminding is improved, the effectiveness of reminding information is improved when the frequency of the reminding information is increased, and the effectiveness is reduced when the frequency of the reminding information is increased.

Preferably, the management module updates the relevant calculated values based on changes in the properties of the engineering object. For example, when the specification of the engineering object changes, the information change monitoring module sends reminding information to the purchase management module. When the purchase management module determines the corresponding purchase unit price, the cost management module automatically updates the current cost evaluation value according to the unit price change of the engineering object. The change of the attribute parameters of the engineering objects enables each management module to automatically update and manage, so that links of manual management are reduced, and storage occupied space of repeated data is also reduced. By the arrangement, each management module can timely find out change information of important attributes, so that the management module can send reminding information to related personnel, and workers can timely adjust strategies according to the reminding information.

The management module at least comprises a management module which establishes connection with the server in a wired or wireless mode respectively. The management modules are, for example, a design management module 101, a purchase management module 102, a construction management module 103, a debugging management module 104, a progress management module 105, a cost management module 106, a quality management module 107, a handover management module 108, a human resources management module 109, a document management module 110, and a GIS management module 200.

The management module further includes a registration module. The registration module is used for registering the engineering object. For example, in the project design process, the objects are registered progressively and in detail according to the actual requirements of the project, in the feasibility research stage, the key equipment and the like are designed and registered, and in the detailed design stage, all engineering objects to be built are registered.

The design management module 101 is used for engineering design and can quickly query changes in object design parameters during the design process. For example, the engineering design can specify information such as a logical number of a position of an engineering object, a design temperature, a pressure, and a space coordinate.

The purchase management module 102 is used for responding to the change of engineering design in time through the state prompt of the engineering object, and changing the purchase strategy in time, so that the purchase cost is saved. In the purchasing process, the updated engineering design is classified and sub-packaged based on engineering construction objects, and all links involved in the purchasing process such as a demand plan, a purchasing plan, a bidding plan, an order, a contract, equipment supervision, material warehouse-in and warehouse-out and other activities are connected in series through the engineering objects, so that the problem of repeated account recording in the purchasing process is solved, and the purchasing data alignment is realized.

The construction management module 103 is used for timely recording actual data of a construction site, reducing the problems of multi-head input of construction data and uneven data, and guaranteeing timeliness and effectiveness of the data.

The debug management module 104 is used for automatically performing debug work. Firstly, debugging contents are formed into a debugging package, then construction state control is carried out based on engineering objects, after the state is reached, a debugging task is automatically started, the debugging task can be automatically started through object state transmission, the time of personnel statistics, comparison and analysis is saved, planning is assisted, and the quality safety problem that the engineering construction is focused by manpower is released.

The progress of the progress management module 105 includes design progress management, purchase progress management, construction progress management, debugging progress management, and completion progress management. The dimension concerned by each stage is different, the design stage mainly aims at the examination and publishing conditions of the design model and the design document, the purchasing stage mainly aims at the purchasing progress of each purchasing package, the construction stage aims at the construction processes of different devices, different professions and different procedures, the debugging stage mainly aims at the conditions of a system, a subsystem and a debugging package, and the handover stage mainly aims at the handover list of the factory entity object. Therefore, the progress of each stage cannot be completed completely through the relationship of the front and back. However, in the whole process, the business is very concerned about what stage a certain object is designed, purchased and the like, and the construction plan is arranged according to the expected arrival condition of the purchase, so that the plan can be adjusted in time according to the change condition. Therefore, the project object structures are required to be used for being related to different progress plans one by one, so that the indirect association between the progress plans is realized, and the collaborative office between the plans is realized.

The cost management module 106 is used to estimate the cost of the project. The engineering construction cost management is mainly divided into two parts of engineering quantity management and object purchase management. In the early stage of engineering construction, cost estimation is required. The estimation work is a source of cost management, and the estimation can be quickly and scientifically compiled by associating the cost in the project with the engineering object according to the historical experience data of specific engineering objects. Contract, payment, change and settlement information can be counted based on the cost of the engineering object, the association with progress activities can be indirectly realized through the association of the cost decomposition structure and the engineering construction object structure, the problem that the cost decomposition structure and the progress decomposition structure are not unified is solved, and winning value analysis can be conveniently carried out.

The quality management module 107 is configured to obtain quality inspection content by retrieving acceptance rules and specifications of a class in which an engineering object is located, and perform timely inspection and entry into the system after completing a job. If the inspection is not acceptable, tracking is performed based on the object until the inspection is acceptable or disabled. Based on quality inspection of the object and statistics based on attributes of the object, such as based on class, specialty, date, etc. of the object.

The handover management module 108 is configured to form a handover list based on the engineering object in the engineering object finishing handover stage, so as to effectively guide the handover work. The contents of the handover object include a factory entity acceptance, a factory object attribute and a material acceptance. The method is based on the collected data and data of the engineering object in the early stage, can reduce the handover difficulty, improve the handover efficiency, improve the handover data quality and provide a solid data base for operation and maintenance.

The human resource management module 109 is configured to record execution data according to execution of a process of checking and accepting work or quality by a person, count conditions of the person executing each stage on a certain engineering object, and count conditions of the work quality, and provide a data base for performance evaluation of human resources.

The document management module 110 is configured to store data, organize and present objects in dimensions, and automatically translate the data into information such as related design documents, work process records documents, quality documents, debug results documents, completion acceptance documents, and the like. The document management module 110 may be a server or a storage component. The storage component includes an application specific integrated chip, a server, a magnetic disk, a hard disk, etc. having an information storage function.

The GIS management module 200 is used for visually displaying a three-dimensional GIS space of engineering. The three-dimensional GIS space is a visual display form of the engineering object. Through the three-dimensional GIS model, the engineering construction objects and the information of each management dimension are connected in series, and the design drawing information, the design parameter table, the purchase order information, the construction state and the like can be checked in the three-dimensional GIS model. The invention is beneficial to reducing communication barriers of all professionals through visualization, and also provides a convenient tool for construction and delivery of a higher-quality process.

The operation principle of the engineering construction management system of the invention is shown as follows.

In response to parameter change information of a pre-specified attribute of at least one engineering object issued by the design management module 101, the procurement management module 102 and/or the construction management module 103 associated with the pre-specified attribute adjusts relevant procurement parameter information and/or construction parameter information based on the parameter change information and issues at least one reminder information.

In response to parameter change information of a pre-specified attribute of at least one engineering object issued by the procurement management module 102, the construction management module 103 associated with the pre-specified attribute compares the parameter change information of the engineering object with necessary engineering objects involved in a preset time frame. In the case that the engineering object belongs to a necessary engineering object, the construction management module 103 sends out at least one reminding message. The necessary engineering object in the invention refers to an engineering object related to the current construction stage, and the attribute change of the engineering object can influence the current construction stage. I.e. the list of necessary engineering objects is changed based on the progress of the construction phase. The list of necessary engineering objects is a preset list associated with the construction phase.

Preferably, the construction management module 103 determines the progress of the engineering object based on image information collected by a plurality of sensors, the debugging management module 104 selects the debugging content and performs automatic debugging based on attribute information of the engineering object in response to a signal of the installation completion status sent by the construction management module 103, and the construction management module 103 feeds back the debugging result to the progress management module 105. For example, the construction management module 103 determines an image change of construction of an engineering object based on image information acquired by a plurality of sensors, and transmits a reminder to the progress management module 105 when a change amount of a certain engineering object reaches a preset change unit limit. For example, when the construction management module 103 judges that the installation length of the pipe reaches a preset position and a preset length by an image, the construction management module 103 automatically judges that the pipe installation is completed. For example, when the construction management module 103 judges by an image that every 5% increase in the installation completion amount of the pipe, the construction management module 103 sends progress alert information to the progress management module 105. Wherein. The construction management module is capable of identifying a number of engineering objects such as pipelines, engineering bodies, part structures and the like based on the acquired point cloud images. Compared with the construction condition and the construction progress of the engineering object acquired in a periodic manner, the method and the device have the advantages that the change unit limit value of the engineering object is preset to enable the engineering object to be actively reminded when the engineering object reaches the preset change, and the speed change of the construction progress can be intuitively checked based on the time period change corresponding to the same change unit limit value. Moreover, the invention actively forms the change of the engineering progress based on the change unit limit value of the engineering object, thereby avoiding the defect of missing the construction of the key progress of the engineering object. Preferably, the change unit limit value of the construction of the engineering object can be adjusted, and under the condition that the change unit limit value is reduced, the time required for generating one change unit limit value for the engineering object is correspondingly reduced, so that the accurate monitoring of the engineering object in a critical period is facilitated.

Preferably, for the human resource management module 109, when the association between the increase of the worker and the progress change of the engineering object is difficult to judge after the worker is deployed, the human resource management module 109 is difficult to perform scientific deployment of the worker or to scientifically increase or decrease the constructor. Under the condition that the engineering object is monitored by the change unit limit value of the engineering object, the working time corresponding to the same change unit limit value can intuitively display the association relation between the change of constructors and the progress change of the engineering object, and the association relation comprises positive correlation, negative correlation, unobvious association and the like. The human resource management module 109 can obtain the association relationship between human resource adjustment and construction of the engineering object based on the construction information collected by the construction management module 103 and the human resource information corresponding to the engineering object. For example, when a worker is added to the construction of the engineering object, the change time corresponding to the change unit limit is reduced, and the worker is effectively mobilized. When a worker is added to the construction of the engineering object, the change time corresponding to the change unit limit is not changed or prolonged, and the worker is not mobilized. The association relationship between the human power change and the change unit limit value of the engineering object can be stored as history information. The human resource module 109 can construct a more scientific human capability assessment based on the association relationship between human power change and the change unit limit value of the engineering object as history data, so that the staff can be scientifically and effectively allocated, and the construction progress of the engineering object can be performed according to the preset process progress.

Preferably, the schedule management module 105 adjusts attribute information associated with the construction management module 103 and/or the debugging management module 104 based on the attribute parameter information of the engineering object fed back by the design management module 101, the purchase management module 102, the construction management module 103 and/or the debugging management module 104, so that a time interval between the purchase schedule, the construction schedule and the debugging schedule of the engineering object is within a preset time range.

Preferably, the cost management module 106 updates the estimated information of the engineering cost based on procurement information of a number of engineering objects and/or changes in engineering progress, wherein,

When the procurement information and/or the change in the progress of the project and/or the accumulated change reach a defined value, the cost management module 106 updates the estimated information of the project cost,

The cost management module 106 maintains current estimated information of the engineering cost when the procurement information and/or the change in engineering progress and/or the cumulative change does not reach a limit value.

Preferably, the quality management module 107 sends tracking instructions to the progress management module 105 based on the reject status information of the engineering object. When the latest debugging result of the engineering object is sent to the progress management module 105 by the debugging management module 104, the progress management module 105 sends out quality acceptance reminding information in response to the tracking instruction. Or the quality management module 107 transmits a handover instruction to the handover management module 108 based on the pass status information of the engineering object, and the handover management module 108 responds to the handover instruction and extracts the attribute parameters of the engineering object to generate a handover manifest.

Preferably, in response to the project preparation progress information sent by the progress management module 105 based on a preset project progress node, the human resources management module 109 sends attribute information of the project object to the schedulable personnel terminal based on the historical human resources information corresponding to the project preparation progress.

Preferably, the human resource management module 109 updates the constructor corresponding to the handover information to the person to be scheduled based on the handover information transmitted by the handover management module 108.

The invention also provides an engineering construction management method of the engineering object corresponding to the engineering construction management system of the engineering object. The method comprises the following steps:

establishing association relation between each attribute parameter of the same engineering object and each management module;

In response to parameter change information of a pre-specified attribute of at least one engineering object sent by the design management module 101, the purchase management module 102 and/or the construction management module 103 associated with the pre-specified attribute adjusts related purchase parameter information and/or construction parameter information based on the parameter change information and sends out at least one reminding information;

In response to parameter change information of a pre-specified attribute of at least one engineering object sent by the purchase management module 102, the construction management module 103 associated with the pre-specified attribute compares the parameter change information of the engineering object with necessary engineering objects involved in a preset time range, and in case that the engineering object belongs to the necessary engineering object, the construction management module 103 sends at least one reminding information.

In the prior art, when an operator views the attribute of an engineering object, the attribute is classified from the attribute category. The operator needs to find the attribute data of the target engineering object from the attribute data of the same class, which obviously increases the transmission quantity of the data and the time consumption of searching.

The invention uses engineering object as core to set the association relation of attribute data. When an operator selects to view the attribute data of the engineering object at any one terminal, the operator directly clicks the engineering object to be selected, and the server can send and display each attribute category of the engineering object to the terminal, so that the data transmission quantity between the terminal and the server is reduced. The operator only needs to select required attribute data from the current attribute category to view, so that the time consumption of the operator for searching information is reduced.

It should be noted that the above-described embodiments are exemplary, and that a person skilled in the art, in light of the present disclosure, may devise various solutions that fall within the scope of the present disclosure and fall within the scope of the present disclosure. It should be understood by those skilled in the art that the present description and drawings are illustrative and not limiting to the claims. The scope of the invention is defined by the claims and their equivalents. The description of the invention encompasses multiple inventive concepts, such as "preferably," "according to a preferred embodiment," or "optionally," all means that the corresponding paragraph discloses a separate concept, and that the applicant reserves the right to filed a divisional application according to each inventive concept.

Claims (9)

1. The engineering construction management system of an engineering object is characterized in that each attribute parameter of the same engineering object and each management module arranged in terminal equipment establish an association relation, wherein the attribute parameter of the engineering object is a dynamic attribute parameter which can be updated by at least one management module, and the dynamic attribute parameter of the engineering object at least comprises a number, specification information, space coordinates, purchase information, unit price information, data information, construction progress information, acceptance information, debugging information and handover information;

The management module at least comprises a design management module (101), a purchase management module (102) and a construction management module (103) which are respectively connected with the server in a wired or wireless mode;

In response to parameter change information of a pre-specified attribute of at least one engineering object sent by the design management module (101), the purchasing management module (102) and/or the construction management module (103) associated with the pre-specified attribute adjusts related purchasing parameter information and/or construction parameter information based on the parameter change information and sends at least one reminding information;

responding to parameter change information of pre-designated attributes of at least one engineering object sent by the purchase management module (102), comparing the parameter change information of the engineering object with a necessary engineering object which is related to the current construction stage and has attribute change capable of influencing the current construction stage and is related to a preset time range by a construction management module (103) related to the pre-designated attributes, and sending at least one reminding message by the construction management module (103) when the engineering object belongs to the necessary engineering object;

the property parameters are associated with engineering objects, and the property parameter categories are associated with at least one management module,

And the management module extracts dynamic attribute parameters associated with the engineering object based on a preset attribute list and forms dynamic management data of the engineering object.

2. The engineering construction management system of an engineering object according to claim 1, further comprising a debugging management module (104),

The construction management module (103) determines the progress of the engineering object based on image information acquired by a plurality of sensors,

In response to a signal of an installation completion state transmitted by the construction management module (103), the debugging management module (104) selects debugging contents based on attribute information of an engineering object and performs automated debugging, and the construction management module (103) feeds back a debugging result to the progress management module (105).

3. The engineering construction management system of an engineering object according to claim 1 or 2, further comprising a progress management module (105),

The progress management module (105) adjusts attribute information associated with the construction management module (103) and/or the debugging management module (104) based on the attribute parameter information of the engineering object fed back by the design management module (101), the purchase management module (102), the construction management module (103) and/or the debugging management module (104) so that the time interval between the purchase progress, the construction progress and the debugging progress of the engineering object is within a preset time range.

4. The engineering construction management system of an engineering object according to claim 1, further comprising a cost management module (106),

The cost management module (106) updates the estimated information of the engineering cost based on procurement information of a number of engineering objects and/or changes in engineering progress, wherein,

When the procurement information and/or the change in the progress of the project and/or the accumulated change reach a limit value, the cost management module (106) updates the estimated information of the project cost,

The cost management module (106) maintains current estimated information of the engineering cost when the procurement information and/or the change in engineering progress and/or the accumulated change does not reach a limit value.

5. The engineering construction management system of an engineering object according to claim 2, further comprising a quality management module (107) and a handover management module (108),

The quality management module (107) sends tracking instructions to the progress management module (105) based on the reject status information of the engineering object,

When the latest debugging result of the engineering object is sent to the progress management module (105) by the debugging management module (104),

In response to the tracking instruction, the progress management module (105) sends out quality acceptance reminding information; or alternatively

The quality management module (107) sends a handover instruction to the handover management module (108) based on the pass status information of the engineering object, the handover management module (108) responding to the handover instruction and extracting attribute parameters of the engineering object to generate a handover manifest.

6. The engineering construction management system for an engineering object according to claim 3, further comprising a human resource management module (109),

In response to project preparation progress information sent by the progress management module (105) based on a preset project progress node, the human resource management module (109) sends attribute information of a project object to a schedulable personnel terminal based on historical human resource information corresponding to the project preparation progress.

7. The engineering construction management system of an engineering object according to claim 6, wherein the human resource management module (109) updates a constructor corresponding to handover information to a person to be scheduled based on the handover information transmitted by the handover management module (108).

8. An engineering construction management method for an engineering object, which is characterized by at least comprising the following steps:

Establishing an association relation between each attribute parameter of the same engineering object and each management module arranged in the terminal equipment, wherein the attribute parameters of the engineering object are dynamic attribute parameters which can be updated by at least one management module, and the dynamic attribute parameters of the engineering object at least comprise numbers, specification information, space coordinates, purchase information, unit price information, data information, construction progress information, acceptance information, debugging information and handover information;

In response to parameter change information of a pre-specified attribute of at least one engineering object sent by a design management module (101), a purchasing management module (102) and/or a construction management module (103) associated with the pre-specified attribute adjusts related purchasing parameter information and/or construction parameter information based on the parameter change information and sends at least one reminding information;

responding to parameter change information of pre-designated attributes of at least one engineering object sent by the purchase management module (102), comparing the parameter change information of the engineering object with a necessary engineering object which is related to the current construction stage and has attribute change capable of influencing the current construction stage and is related to a preset time range by a construction management module (103) related to the pre-designated attributes, and sending at least one reminding message by the construction management module (103) when the engineering object belongs to the necessary engineering object;

the property parameters are associated with engineering objects, and the property parameter categories are associated with at least one management module,

And the management module extracts dynamic attribute parameters associated with the engineering object based on a preset attribute list and forms dynamic management data of the engineering object.

9. The engineering construction management method of an engineering object according to claim 8, wherein the method further comprises:

the construction management module (103) determines the progress of the engineering object based on image information acquired by a plurality of sensors,

In response to a signal of an installation completion state transmitted by the construction management module (103), the debugging management module (104) selects debugging contents based on attribute information of the engineering object and performs automated debugging, and the construction management module (103) feeds back a debugging result to the progress management module (105).