CN110880097A - Project progress simulation display method and device - Google Patents
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Abstract
The application discloses a method for displaying engineering progress in a simulation mode, which comprises the following steps: importing a construction progress plan; importing an engineering management part tree; establishing a first associated data model; the first associated data model is an association relation between the work task item and the engineering management part; acquiring a three-dimensional model of an engineering project; establishing a second associated data model; storing a planned progress simulation data model of the engineering project based on the first associated data model and the second associated data model; and forming a planned progress simulation construction state of the engineering project on a terminal interface by the planned progress simulation data model corresponding to a preset time period. The design of the method can conveniently and visually display the planned schedule of the engineering project, so that the rationality of the schedule can be checked conveniently. In addition, this application still discloses an engineering progress simulation display device.
Description
Technical Field
The application relates to the technical field of project progress display, in particular to a project progress simulation display method and device.
Background
With the development of science and technology, the application of information display methods is more and more extensive, and how to provide a more intuitive information display mode for users has become an important research direction.
In the construction process of the capital construction project, the progress plans compiled by the construction units may not be good enough in consideration of mutual influence of multi-professional and cross-regional operations in the compiling process, and meanwhile, the progress plans cannot be executed according to the plan due to the influence of complex field adaptive factors in the executing process. Therefore, in the planning stage, how to conveniently and intuitively check the rationality of the schedule is a problem to be solved by those skilled in the art.
In addition, in the actual construction stage, the existing engineering progress is usually displayed in a report form, although the engineering progress display mode provides convenience for a user to know the engineering progress to a certain extent, the engineering progress display mode is displayed through at least one piece of information in the report form, so that the problem that the engineering progress is not displayed visually enough often exists, especially when the information in the engineering progress is more, the user needs to know the engineering progress from a large amount of information, and the time is wasted. In view of the above, a method and a system for displaying the project progress in real time are provided to avoid the situations that the project progress is not displayed intuitively and the user cannot conveniently and quickly know the project progress due to displaying the project progress in a report form in the prior art, and a problem to be solved by those skilled in the art is also urgently needed.
Disclosure of Invention
The technical problem to be solved by the application is to provide a project progress simulation display method, and the design of the method can conveniently and visually display the project progress of a project, so that the rationality of the progress plan can be checked conveniently. In addition, another technical problem that this application will solve is to provide a project progress simulation display device.
In order to solve the foregoing technical problem, a first aspect of the embodiments of the present application provides a method for displaying engineering progress simulation, including:
importing a construction progress plan, wherein the construction progress plan comprises one or more work task items, and the work task items comprise planned start time and planned completion time;
importing an engineering management part tree which is of a hierarchical structure; the project management part tree comprises at least one project management part module; the project management part module comprises at least one project management part; the project management site includes at least one project component;
establishing a first associated data model, and determining the planned start time and the planned completion time of each engineering management part; the first associated data model is an association relation between the work task item and the engineering management part;
acquiring a three-dimensional model of an engineering project, wherein the three-dimensional model comprises each engineering component in the project;
establishing a second associated data model, wherein the second associated data model is an association relation between the engineering part and the three-dimensional model, and members with the same management attribute in the three-dimensional model correspond to the same engineering part;
storing a planned progress simulation data model of the engineering project based on the first associated data model and the second associated data model; the planning progress simulation data model corresponds to a preset time period, and a planning progress simulation construction state of the engineering project is formed on a terminal interface; the construction state includes three types: an unestablished state, a constructed state, and the three different constructed states are displayed with different colors or marks.
Optionally, the method further includes:
and receiving a preset time period input by an operator, and generating a corresponding planned progress simulation construction state of the engineering project on the terminal interface based on the planned progress simulation data model.
Optionally, the method further includes:
and receiving a preset time period input by an operator, and generating a corresponding planned progress simulation construction state of the engineering project on the terminal interface based on the planned progress simulation data model.
Optionally, the method further includes:
importing original work volume of a contract of an engineering project, wherein the original work volume of the contract comprises a list code, a list name, project characteristics, a list work volume and list unit price information;
establishing a third associated data model, and determining the engineering quantity and unit price information of each engineering management part; the third correlation data model is the correlation between the project management part and the original project amount list;
generating and storing a planned fund data model between a predetermined time period and a corresponding planned fund expenditure based on the first associated data model and the third associated data model and based on the total construction period of the engineering project;
generating a projected fund curve on the terminal interface based on the stored projected fund data model based on the predetermined time period input by the operator.
Optionally, the method further includes:
importing construction resource classification coding data;
establishing a fourth associated data model, and determining construction resources required to be consumed and specific quantity required to be consumed by each engineering management part; the fourth correlation data model is the correlation between the engineering management part and the corresponding construction resources required to be consumed and the specific consumed quantity;
generating and storing a resource plan consumption data model between a preset time period and corresponding resource plan consumption based on the first associated data model and the fourth associated data model and the whole construction period of the engineering project;
and generating a resource plan consumption curve on the terminal interface based on the stored resource plan consumption data model based on the preset time period input by the operator.
In addition, in order to solve the above technical problem, a second aspect of the embodiments of the present application provides an engineering progress simulation display device, including:
the system comprises a first importing unit, a second importing unit and a third importing unit, wherein the first importing unit is used for importing a construction progress plan, the construction progress plan comprises one or more work task items, and the work task items comprise planned start time and planned completion time;
the second import unit is used for importing an engineering management part tree which is of a hierarchical structure; the project management part tree comprises at least one project management part module; the project management part module comprises at least one project management part; the project management site includes at least one project component;
the first establishing unit is used for establishing a first associated data model and determining the planned start-up time and the planned completion time of each project management part; the first associated data model is an association relation between the work task item and the engineering management part;
the system comprises an acquisition unit, a processing unit and a display unit, wherein the acquisition unit is used for acquiring a three-dimensional model of an engineering project, and the three-dimensional model comprises each engineering component in the project;
the second establishing unit is used for establishing a second associated data model, wherein the second associated data model is an association relation between the engineering part and the three-dimensional model, and members with the same management attribute in the three-dimensional model correspond to the same engineering part;
the first storage unit is used for storing a planned progress simulation data model of the engineering project based on the first associated data model and the second associated data model; the planning progress simulation data model corresponds to a preset time period, and a planning progress simulation construction state of the engineering project is formed on a terminal interface; the construction state includes three types: an unestablished state, a constructed state, and the three different constructed states are displayed with different colors or marks.
In the application, a method for displaying engineering progress simulation is provided, which includes:
importing a construction progress plan, wherein the construction progress plan comprises one or more work task items, and the work task items comprise planned start time and planned completion time;
importing an engineering management part tree which is of a hierarchical structure; the project management part tree comprises at least one project management part module; the project management part module comprises at least one project management part; the project management site includes at least one project component;
establishing a first associated data model, and determining the planned start time and the planned completion time of each engineering management part; the first associated data model is an association relation between the work task item and the engineering management part;
acquiring a three-dimensional model of an engineering project, wherein the three-dimensional model comprises each engineering component in the project;
establishing a second associated data model, wherein the second associated data model is an association relation between the engineering part and the three-dimensional model, and members with the same management attribute in the three-dimensional model correspond to the same engineering part;
storing a planned progress simulation data model of the engineering project based on the first associated data model and the second associated data model; the planning progress simulation data model corresponds to a preset time period, and a planning progress simulation construction state of the engineering project is formed on a terminal interface; the construction state includes three types: an unestablished state, a constructed state, and the three different constructed states are displayed with different colors or marks.
In the method design, a construction progress plan, a project management part tree and a three-dimensional graph of a project are imported, and a corresponding associated data model is established, so that a plan progress simulation data model of the project can be conveniently stored, and the plan progress simulation data model corresponds to a preset time period and forms a plan progress simulation construction state of the project on a terminal interface; the construction state includes three types: an unestablished state, a constructed state, and the three different constructed states are displayed with different colors or marks. Therefore, when the operator inputs a corresponding preset time period, such as a certain month or a certain week, the project plan progress at the moment can be displayed very intuitively.
In conclusion, the design of the method can conveniently and intuitively display the planned schedule of the engineering project, so that the rationality of the schedule can be checked conveniently.
In addition, the present application provides an engineering progress simulation display device, which has the same technical effect as the method described above, and is not repeated herein.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and those skilled in the art can also obtain other drawings according to the drawings without creative efforts.
FIG. 1 is a logic flow diagram of a method for displaying engineering progress simulation in an embodiment of the present application;
fig. 2 is a functional block diagram of an engineering progress simulation display device according to an embodiment of the present application.
Detailed Description
In order to make the technical solutions of the present invention better understood, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention.
In some of the flows described in the present specification and claims and in the above figures, a number of operations are included that occur in a particular order, but it should be clearly understood that these operations may be performed out of order or in parallel as they occur herein, with the order of the operations being indicated as 101, 102, etc. merely to distinguish between the various operations, and the order of the operations by themselves does not represent any order of performance. Additionally, the flows may include more or fewer operations, and the operations may be performed sequentially or in parallel. It should be noted that, the descriptions of "first", "second", etc. in this document are used for distinguishing different messages, devices, modules, etc., and do not represent a sequential order, nor limit the types of "first" and "second" to be different.
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1, fig. 1 is a logic flow diagram of a method for displaying engineering progress simulation in an embodiment of the present application.
As shown in fig. 1, in an embodiment, the method for displaying the engineering progress simulation provided by the present application includes:
step S101: importing a construction progress plan, wherein the construction progress plan comprises one or more work task items, and the work task items comprise planned start time and planned completion time;
step S102: importing an engineering management part tree which is of a hierarchical structure; the project management part tree comprises at least one project management part module; the project management part module comprises at least one project management part; the project management site comprises at least one project component;
step S103: establishing a first associated data model, and determining the planned start time and the planned completion time of each engineering management part; the first associated data model is an associated relation between the work task item and the engineering management part;
step S104: acquiring a three-dimensional model of an engineering project, wherein the three-dimensional model comprises all engineering components in the project;
step S105: establishing a second associated data model, wherein the second associated data model is an association relation between the engineering part and the three-dimensional model, and the components with the same management attribute in the three-dimensional model correspond to the same engineering part;
step S106: storing a planned progress simulation data model of the engineering project based on the first associated data model and the second associated data model; forming a planned progress simulation construction state of the engineering project on a terminal interface corresponding to a preset time period by using the planned progress simulation data model; the construction state includes three types: an unestablished state, a constructed state, and the three different constructed states are displayed with different colors or marks.
In the method design, a construction progress plan, a project management part tree and a three-dimensional graph of a project are imported, and a corresponding associated data model is established, so that a plan progress simulation data model of the project can be conveniently stored, and the plan progress simulation data model corresponds to a preset time period and forms a plan progress simulation construction state of the project on a terminal interface; the construction state includes three types: an unestablished state, a constructed state, and the three different constructed states are displayed with different colors or marks. Therefore, when the operator inputs a corresponding preset time period, such as a certain month or a certain week, the project plan progress at the moment can be displayed very intuitively.
In conclusion, the design of the method can conveniently and intuitively display the planned schedule of the engineering project, so that the rationality of the schedule can be checked conveniently.
In the above-described embodiments, further improvements can be made.
For example, a predetermined time period input by an operator is received, and a planned progress simulation construction state of a corresponding engineering project is generated on a terminal interface based on a planned progress simulation data model. The preset time period can be a certain month, a certain week and the like, and the corresponding project progress can be automatically output on the terminal interface based on the corresponding plan progress simulation data model. And is presented by way of a three-dimensional graphic.
Through the technical scheme, the three-dimensional model of the actual project progress can be further displayed, and the display can be automatically output when a preset time period is available in a certain month and a certain week.
Further, in the above-described embodiment, the following modifications can be made.
For example, the method further comprises the following steps:
importing original work volume of a contract of an engineering project, wherein the original work volume of the contract comprises a list code, a list name, project characteristics, a list work volume and list unit price information;
establishing a third associated data model, and determining the engineering quantity and unit price information of each engineering management part; the third correlation data model is the correlation between the project management part and the original project amount list;
generating and storing a planned fund data model between a predetermined time period and a corresponding planned fund expenditure based on the first associated data model and the third associated data model and based on the total construction period of the engineering project;
generating a projected fund curve on the terminal interface based on the stored projected fund data model based on the predetermined time period input by the operator.
In a specific application scenario, the above scheme may be implemented as follows:
specifically, in the above steps, the project management part tree of the project is sorted and built according to the construction range of the project.
The engineering components with the same management attributes correspond to the same engineering management part. For example, a frame beam, a frame column, a structural column, a floor slab and the like in the building engineering, the system further comprises an engineering management part module, the engineering management part module comprises a plurality of engineering management parts, wherein engineering components with the same management attribute correspond to the same engineering management part, for example, all the frame beams on the same layer are divided into an engineering management part A. The project management part can be understood as a management object of a project, and the division of the management object is customized, such as: the engineering components can be a plurality of layers, one engineering component can be one layer, or one engineering component can be a plurality of layers. The built project management part also comprises an image progress index associated with each project management part and a planned image progress project amount corresponding to each index.
And the construction party sorts and records the bid engineering quantity list into the platform. And the original project amount list of the sorting and inputting platform needs to be checked and locked by a construction party. The locked work volume list cannot be modified or adjusted.
The imported original engineering quantity list comprises list codes, list names, item characteristics, list engineering quantities and list unit price information.
Decomposing the sorted and input original project amount list into each specific project management part, and determining the list project amount associated with each project management part.
Such as "list code in original engineering quantity list: BT9101B25001, list name: concrete cast-in-place pile' with a total contract amount of 3000m3The project management parts related to the current list comprise 1# pile foundation, 2# pile foundation and … … # pile foundation of the main control building145# pile foundation, still include main basic 1# pile foundation, 2# pile foundation, … … 15# pile foundation, then need confirm the corresponding "list code of every engineering management position according to the construction drawing: BT9101B25001, list name: concrete cast-in-place pile' specific engineering quantity: master control building 1# pile foundation 15m3And 2# pile foundation 15m3… … 145# pile foundation 20m3And decomposing the engineering quantity corresponding to each part related to the list in turn.
And decomposing the engineering parts of other original engineering quantity lists in sequence by the same method.
After the original project amount list is decomposed, the project management part has the information of the related list project amount and list unit price.
And importing a progress plan of the project, and establishing an association relation between a project progress plan task item and a project management part. The imported schedule includes one or more work task items with a schedule start time and a schedule completion time. And establishing an incidence relation between the task item and the engineering management part.
Acquiring actual progress filling information of a constructor, and according to the acquired actual progress filling information, synchronously acquiring the construction state of a project part: not built, under construction and built.
For a project site whose state is established, the information includes an actual start time and an actual completion time.
An automatically generated projected funds curve is generated. The horizontal axis of the projected funds curve is the month and the vertical axis is the projected funds amount.
After the incidence relation between the task item and the project part is established, the project management part has the plan starting time and the plan finishing time.
Horizontal axis: collecting according to the planned completion time of the engineering management part;
longitudinal axis: and calculating the theoretical cost of the engineering management part (the associated list engineering quantity and the list price, and if a plurality of lists are associated, taking the total price of the plurality of lists).
And automatically generating a value-of-production fund curve according to the established project part. The horizontal axis is the month and the vertical axis is the amount of finished output.
Horizontal axis: collecting according to the actual completion time of the engineering management part;
longitudinal axis: calculating the theoretical cost of the project management part (list project amount associated with the price of the project, if there are multiple lists associated with the project management part, the price of the multiple lists is taken)
The yield-capital curve is a dynamic process that dynamically changes according to the actual project management site completed each month.
Further, the following improvements can be made.
For example, importing construction resource classification coding data;
establishing a fourth associated data model, and determining construction resources required to be consumed and specific quantity required to be consumed by each engineering management part; the fourth correlation data model is the correlation between the engineering management part and the corresponding construction resources required to be consumed and the specific consumed quantity;
generating and storing a resource plan consumption data model between a preset time period and corresponding resource plan consumption based on the first associated data model and the fourth associated data model and the whole construction period of the engineering project;
and generating a resource plan consumption curve on the terminal interface based on the stored resource plan consumption data model based on the preset time period input by the operator.
In a specific application scenario, the above scheme may be implemented as follows:
importing construction resource classification coded data
And importing and acquiring the construction resource classified coding data of the project according to the construction requirement of the project. The imported construction resource classification catalogue comprises a resource name, a resource code and a dimension;
the construction resource library is divided into three categories of manpower, material and equipment according to the categories. Each resource classification code is created according to a certain classification rule. For example, the material first grade is classified into concrete, reinforcing steel bar, concrete and the like, and there are second grade classifications such as ordinary concrete, special concrete, novel concrete under the concrete first grade classification again, divide into specific different construction resources according to different concrete reference numbers under the ordinary concrete second grade classification again: c10, C15, C20, C25, and the like.
Establishing incidence relation between resource classification coded data and engineering management part
And associating the imported construction resource data with the specific engineering management positions, and determining the construction resources required to be consumed and the specific quantity required to be consumed by each engineering management position.
For example, the engineering management part 000# pier 002# pile foundation, the construction resources required to be consumed according to the construction drawing comprise C40 common concrete, phi 25HRB400 deformed steel bar, phi 16HRB400 deformed steel bar, phi 8HPB300 smooth round steel bar, concrete, rotary drilling rig, concrete tank truck and 25T crane, and the planned consumption amounts are respectively: 45.5m3, 1.45t, 0.98t, 1.22t, 11 workdays, 3 workdays, 6 shifts, 0.6 shifts and 0.8 shifts.
Resource plan consumption curve
According to the method, the resource plan consumption curve can be automatically generated, and the resource plan consumption curve generates data according to different months.
Horizontal axis: time of day, month of month.
Longitudinal axis: and counting the consumed resources according to three major categories of manpower, materials and materials.
Through resource consumption curve analysis, resource consumption data of different months can be seen, the resource consumption peak is planned and effectively controlled, and resource investment is reasonably increased or a progress plan is adjusted.
In a specific application scenario, the above technical solution can be implemented as follows:
specifically, in the above steps, the project management part tree of the project is sorted and built according to the construction range of the project.
The engineering components with the same management attributes correspond to the same engineering management part. For example, a frame beam, a frame column, a structural column, a floor slab and the like in the building engineering, the system further comprises an engineering management part module, the engineering management part module comprises a plurality of engineering management parts, wherein engineering components with the same management attribute correspond to the same engineering management part, for example, all the frame beams on the same layer are divided into an engineering management part A. The project management part can be understood as a management object of a project, and the division of the management object is customized, such as: the engineering components can be a plurality of layers, one engineering component can be one layer, or one engineering component can be a plurality of layers.
And establishing an incidence relation between the engineering management part tree and the three-dimensional model engineering component according to the imported engineering management part tree. An engineering management site tree may be associated with one or more engineering components.
For example, during modeling, each frame beam and frame column of each floor in a building are an independent engineering component, but the frame beams or frame columns of a floor can be managed as a management part, and then each frame beam engineering component of each floor in the model needs to be associated with one engineering management part of the floor;
or one engineering component may correspond to one engineering management part, for example, a transformer and GIS equipment in the equipment, one transformer is a model engineering component, and at the same time, one transformer is managed as a separate engineering management part, so that one transformer equipment needs to be associated with one transformer engineering management part one to one.
And importing a progress plan of the project, and establishing an association relation between a project progress plan task item and a project management part. The imported schedule includes one or more work task items with a schedule start time and a schedule completion time. And establishing an incidence relation between the task item and the engineering management part. After the task item and the project management part are managed, the project management part inherits the plan starting time and the plan finishing time of the task item.
According to the operation, the project progress simulation operation based on the BIM can be carried out. The project progress simulation is that the earliest starting time and the latest finishing time of the progress plan are used as the starting point and the ending point of the progress simulation time, and the construction state of each day of the project part is automatically displayed by different colors.
When the progress simulation is carried out, according to the planning time information (planning start time and planning completion time) of the project management part corresponding to the BIM model component, the building state of the project part is marked by different colors: semi-permeable blue indicates that the building is not performed, green indicates that the building is performed, and solid color indicates that the building is performed.
Not building: the simulation is carried out to a time earlier than the planned starting time of the project management part;
building a model: the simulation is performed to a time later than or equal to a planning start time of the project management site and earlier than a planning completion time of the project management site;
the method comprises the following steps: the simulation is carried out until the time is later than or equal to the planned completion time of the project management part;
the project construction content and state of a certain day in the future can be displayed through project progress simulation, and the rationality adjustment of the progress plan can be carried out.
In addition, an embodiment of an apparatus is provided in the present application corresponding to the above-mentioned method embodiment, please refer to fig. 2, and fig. 2 is a functional block diagram of a dynamic display method for an engineering project fund curve in an embodiment of the present application.
For example, in an embodiment, as shown in fig. 2, the project progress simulation display device includes:
the system comprises a first import unit, a second import unit and a third import unit, wherein the first import unit is used for importing a construction progress plan, the construction progress plan comprises one or more work task items, and the work task items comprise planned start time and planned completion time;
the second import unit is used for importing an engineering management part tree, and the engineering management part tree is of a hierarchical structure; the project management part tree comprises at least one project management part module; the project management part module comprises at least one project management part; the project management site comprises at least one project component;
the first establishing unit is used for establishing a first associated data model and determining the planned start time and the planned completion time of each project management part; the first associated data model is an associated relation between the work task item and the engineering management part;
the system comprises an acquisition unit, a processing unit and a display unit, wherein the acquisition unit is used for acquiring a three-dimensional model of the engineering project, and the three-dimensional model comprises each engineering component in the project;
the second establishing unit is used for establishing a second associated data model, wherein the second associated data model is an association relation between the engineering part and the three-dimensional model, and the components with the same management attribute in the three-dimensional model correspond to the same engineering part;
the first storage unit is used for storing a planned progress simulation data model of the engineering project based on the first associated data model and the second associated data model; forming a planned progress simulation construction state of the engineering project on a terminal interface corresponding to a preset time period by using the planned progress simulation data model; the construction state includes three types: an unestablished state, a constructed state, and the three different constructed states are displayed with different colors or marks.
It can be clearly understood by those skilled in the art that, for convenience and brevity of description, the specific working processes and technical effects of the above-described systems, apparatuses and units may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.
The above-described embodiments of the apparatus are merely illustrative, and the units described as separate parts may or may not be physically separate, and the parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.
Through the above description of the embodiments, those skilled in the art will clearly understand that each embodiment can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware. With this understanding in mind, the above-described technical solutions may be embodied in the form of a software product, which can be stored in a computer-readable storage medium, such as ROM/RAM, magnetic disk, optical disk, etc., and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the methods of the various embodiments or some parts of the embodiments.
Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.
Claims (5)
1. A project progress simulation display method is characterized by comprising the following steps:
importing a construction progress plan, wherein the construction progress plan comprises one or more work task items, and the work task items comprise planned start time and planned completion time;
importing an engineering management part tree which is of a hierarchical structure; the project management part tree comprises at least one project management part module; the project management part module comprises at least one project management part; the project management site includes at least one project component;
establishing a first associated data model, and determining the planned start time and the planned completion time of each engineering management part; the first associated data model is an association relation between the work task item and the engineering management part;
acquiring a three-dimensional model of an engineering project, wherein the three-dimensional model comprises each engineering component in the project;
establishing a second associated data model, wherein the second associated data model is an association relation between the engineering part and the three-dimensional model, and members with the same management attribute in the three-dimensional model correspond to the same engineering part;
storing a planned progress simulation data model of the engineering project based on the first associated data model and the second associated data model; the planning progress simulation data model corresponds to a preset time period, and a planning progress simulation construction state of the engineering project is formed on a terminal interface; the construction state includes three types: an unestablished state, a constructed state, and the three different constructed states are displayed with different colors or marks.
2. The project progress simulation display method according to claim 1, further comprising:
and receiving a preset time period input by an operator, and generating a corresponding planned progress simulation construction state of the engineering project on the terminal interface based on the planned progress simulation data model.
3. The project progress simulation display method according to claim 1 or 2, characterized by further comprising:
importing original work volume of a contract of an engineering project, wherein the original work volume of the contract comprises a list code, a list name, project characteristics, a list work volume and list unit price information;
establishing a third associated data model, and determining the engineering quantity and unit price information of each engineering management part; the third correlation data model is the correlation between the project management part and the original project amount list;
generating and storing a planned fund data model between a predetermined time period and a corresponding planned fund expenditure based on the first associated data model and the third associated data model and based on the total construction period of the engineering project;
generating a projected fund curve on the terminal interface based on the stored projected fund data model based on the predetermined time period input by the operator.
4. The project progress simulation display method according to claim 1 or 2, characterized by further comprising:
importing construction resource classification coding data;
establishing a fourth associated data model, and determining construction resources required to be consumed and specific quantity required to be consumed by each engineering management part; the fourth correlation data model is the correlation between the engineering management part and the corresponding construction resources required to be consumed and the specific consumed quantity;
generating and storing a resource plan consumption data model between a preset time period and corresponding resource plan consumption based on the first associated data model and the fourth associated data model and the whole construction period of the engineering project;
and generating a resource plan consumption curve on the terminal interface based on the stored resource plan consumption data model based on the preset time period input by the operator.
5. An engineering progress simulation display device, comprising:
the system comprises a first importing unit, a second importing unit and a third importing unit, wherein the first importing unit is used for importing a construction progress plan, the construction progress plan comprises one or more work task items, and the work task items comprise planned start time and planned completion time;
the second import unit is used for importing an engineering management part tree which is of a hierarchical structure; the project management part tree comprises at least one project management part module; the project management part module comprises at least one project management part; the project management site includes at least one project component;
the first establishing unit is used for establishing a first associated data model and determining the planned start-up time and the planned completion time of each project management part; the first associated data model is an association relation between the work task item and the engineering management part;
the system comprises an acquisition unit, a processing unit and a display unit, wherein the acquisition unit is used for acquiring a three-dimensional model of an engineering project, and the three-dimensional model comprises each engineering component in the project;
the second establishing unit is used for establishing a second associated data model, wherein the second associated data model is an association relation between the engineering part and the three-dimensional model, and members with the same management attribute in the three-dimensional model correspond to the same engineering part;
the first storage unit is used for storing a planned progress simulation data model of the engineering project based on the first associated data model and the second associated data model; the planning progress simulation data model corresponds to a preset time period, and a planning progress simulation construction state of the engineering project is formed on a terminal interface; the construction state includes three types: an unestablished state, a constructed state, and the three different constructed states are displayed with different colors or marks.
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