A project management method, system, and storage medium for the environmental impact assessment industry.
By using project management methods and systems to dynamically update project topology diagrams, the inefficiency caused by manual management in the environmental impact assessment industry has been solved, and dynamic and efficient management of environmental impact assessment work has been achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- HANGZHOU ENVIRONMENTAL PROTECTION SCI RES DESIGN CO LTD
- Filing Date
- 2023-03-15
- Publication Date
- 2026-06-30
AI Technical Summary
The current environmental impact assessment industry relies mainly on manual management for project management, resulting in long processes, multi-dimensional data interaction, close interdependence among multiple departments, low dynamic correlation, and impact on work efficiency.
Using project management methods and systems, tasks are generated by obtaining project orders, assigned to project leaders, divided into project sub-items, and a project topology diagram is generated. The diagram is then dynamically updated based on the results of the sub-items. Topology points and lines are used to analyze the correlation and impact of each stage, and a draft for review is generated.
It enables dynamic analysis of environmental impact assessment work, improves the correlation and effectiveness of each stage, and enhances the efficiency and accuracy of project management.
Smart Images

Figure CN116308168B_ABST
Abstract
Description
Technical Field
[0001] This application relates to the technical field of environmental impact assessment project management, and in particular to a project management method, system and storage medium for the environmental impact assessment industry. Background Technology
[0002] Environmental impact assessment (EIA) is a scientific and technological discipline developed based on environmental monitoring technology, pollutant diffusion patterns, the impact of environmental quality on human health, and the self-purification capacity of nature.
[0003] The focus of environmental impact assessment is to demonstrate its preventive function before decision-making and development activities begin. After decision-making or the commencement of development activities, the assessment conclusions are continuously verified through the implementation of environmental monitoring plans and ongoing research, and feedback is provided to decision-makers and builders to further modify and improve their decision-making and development activities.
[0004] Currently, in the environmental impact assessment (EIA) industry, project management throughout the entire EIA process is generally done manually. However, EIA work is characterized by a long process, multi-dimensional data interaction, and close interdependence among multiple departments. It requires a large number of steps and documents, and the project data and work links are relatively scattered. Manual project management methods have significant limitations, and the dynamic correlation between various links is low, resulting in extremely poor EIA work results. Summary of the Invention
[0005] To improve the effectiveness of environmental impact assessment (EIA) work, this application provides a project management method, system, and storage medium for the EIA industry.
[0006] Firstly, this application provides a project management method for the environmental impact assessment industry, which adopts the following technical solution:
[0007] A project management methodology for the environmental impact assessment industry includes the following steps:
[0008] Obtain project orders and generate corresponding project tasks to be assigned based on the project orders;
[0009] Assign the tasks to be assigned to the corresponding project manager;
[0010] Obtain contract signing information, and generate several project sub-items based on the project tasks to be assigned corresponding to the contract signing information. The project sub-items include site survey, data collection, current status monitoring, and compilation of final drafts.
[0011] A project topology diagram is generated based on several project sub-items. The project topology diagram includes topology points generated from the work results of several project sub-items, and several topology points that meet preset association and influence conditions are connected by topology lines.
[0012] The project topology map is dynamically updated at preset time intervals based on the work results of several project sub-items, and the corresponding topology results are obtained based on the project topology map.
[0013] The project draft is generated based on the topology results and the work results of several project sub-items.
[0014] Preferably, assigning the tasks to be assigned to the corresponding project manager includes the following steps:
[0015] Obtain the project classification information from the tasks to be assigned in the project, wherein the project classification information includes at least the field, type, and size of the project;
[0016] Acquire several pre-set capability models on the project manager's end, wherein the capability models are used to characterize the capability information of the corresponding project manager;
[0017] The project classification information is compared with several capability models to obtain the capability model with the highest matching degree, and the project classification information is assigned to the project manager corresponding to the capability model.
[0018] Preferably, generating a project topology map based on several project sub-items, and connecting several topology points that meet preset association influence conditions through topology lines, includes the following steps:
[0019] Generate the total project topology points based on the project orders;
[0020] Based on the results of the on-site survey, several first factor topology points are generated. The results of the on-site survey include at least water samples, topography, population distribution, and factory distribution around the site. They may also include production processes, product plans, raw and auxiliary materials, etc. The several first factor topology points include several endpoints, and the first endpoints of the several first factor topology points are all connected to the total topology point.
[0021] Based on the results of the site survey, a data collection task is obtained; corresponding data is collected based on the data collection task; and a first influencing variable is generated based on the data collection results.
[0022] Substitute the first influencing variable into the first factor topology point respectively, and determine whether several first factor topology points need to be updated;
[0023] If no update is required, a second factor topology point is generated, and the first endpoint of the second factor topology point is connected to the second endpoint of the first factor topology point to generate a topology line;
[0024] If an update is required, a second factor topology point is generated, and a blocking monitoring valve is set between the first endpoint of the second factor topology point and the second endpoint of the first factor topology point. The blocking monitoring valve is used to block the connection between the two topology points and restore the connection between the two topology points when a preset condition is met.
[0025] A second influencing variable is generated based on the results of the current status monitoring.
[0026] Substitute the second influencing variable into the first factor topology point respectively, and determine whether several first factor topology points need to be updated;
[0027] If no update is required, a third factor topology point is generated, and the first endpoint of the third factor topology point is connected to the third endpoint of the first factor topology point to generate a topology line;
[0028] If an update is required, a third factor topology point is generated, and a blocking monitoring valve is set between the first endpoint of the third factor topology point and the third endpoint of the first factor topology point.
[0029] Preferably, the first or second influencing variable is substituted into the first factor topology point to generate the corresponding second or third factor topology point, which specifically includes the following steps:
[0030] Obtain the type corresponding to the first factor topology point;
[0031] Obtain the information with the highest type correlation between the first or second influencing variable and the topological point of the first factor, and substitute the corresponding information into the topological point of the first factor;
[0032] The corresponding second or third factor topological point is generated based on the information with the highest type correlation to the first factor topological point.
[0033] Preferably, after generating the second influencing variable based on the results of the current status monitoring, the method further includes the following steps:
[0034] Determine whether there is information in the second influencing variable that is associated with the blocking monitoring valve between the first factor topology point and the second factor topology point;
[0035] If it exists, determine whether the information meets the recovery conditions of the blocking monitoring valve;
[0036] If the conditions are met, the blocking monitoring valve will restore the connection between the two topological points.
[0037] Preferably, the project topology diagram is dynamically updated based on the work results of several project sub-items, including the following steps:
[0038] The second influencing variable is acquired at preset time intervals, wherein the current status monitoring is a process of maintaining real-time monitoring;
[0039] If the second influencing variable changes, then the second influencing variable is incorporated into the first factor topology point and / or the blocking monitoring valve between the first factor topology point and the second factor topology point;
[0040] The blocking monitoring valve between the first factor topology point and the second factor topology point, and the blocking monitoring valve between the first factor topology point and the third factor topology point, are updated according to the second influencing variable.
[0041] Preferably, obtaining the corresponding topology results based on the project topology diagram includes the following steps:
[0042] Obtain information on all blocking monitoring valves in the blocked state in the project topology diagram;
[0043] Based on the information of the blocking monitoring valve, the first factor topology point, the second factor topology point and / or the third factor topology point at both ends of the blocking monitoring valve are obtained, and two adjacent topology points are defined as an abnormal topology point group.
[0044] The corresponding cause of the anomaly is generated based on the information of the blocking monitoring valve and the abnormal topology point group.
[0045] The topology results are obtained by analyzing the blocking monitoring valve information, abnormal topology point groups, and abnormal causes.
[0046] Preferably, generating a corresponding cause of the anomaly based on the blocking monitoring valve information and the abnormal topology point group includes the following steps:
[0047] Obtain historical project anomaly cases, which are characterized as case information of anomalies in previously completed projects, including at least historical anomaly blocking monitoring valve information, historical anomaly topology point groups, and historical anomaly causes;
[0048] A corresponding exception record library is generated based on the aforementioned historical project exception cases;
[0049] The blocking monitoring valve information and the abnormal topology point group are brought into the abnormal record database to determine whether there are any historical project abnormal cases with high similarity to them.
[0050] If it exists, the historical anomaly cause corresponding to the historical project anomaly case shall be used as the anomaly cause of the blocking monitoring valve information and the anomaly topology point group;
[0051] If it does not exist, an abnormal alarm message and a manual addition option will be output. The manual addition option allows the user to manually add the cause of the abnormality based on the blocking monitoring valve information and the abnormal topology point group.
[0052] Secondly, this application provides a project management system for the environmental impact assessment industry, which adopts the following technical solution:
[0053] A project management system for the environmental impact assessment industry includes a project acceptance module, a project manager's interface, a contract signing module, a report preparation module, a processing module, and a submission module.
[0054] The project acceptance module is used to accept projects and generate project orders;
[0055] The contract signing module is used to sign project contracts and generate corresponding contract signing information;
[0056] The processing module is used to obtain the project order, generate corresponding project tasks to be assigned based on the project order, and assign the project tasks to the corresponding project manager; it is also used to obtain the contract signing information and generate several project sub-items based on the project tasks to be assigned corresponding to the contract signing information.
[0057] The report preparation module is used to carry out projects based on several project sub-items and generate corresponding project sub-item work results. Specifically, the report preparation module includes a site survey module, a data collection module, a current status monitoring module, and a compilation module.
[0058] The processing module is further configured to generate a project topology map based on several project sub-items, the project topology map including topology points generated from the work results of several project sub-items, and several topology points that meet preset association and influence conditions are connected by topology lines; dynamically update the project topology map according to the work results of several project sub-items at preset time intervals, and obtain corresponding topology results based on the project topology map; and generate a project submission draft based on the topology results and the work results of several project sub-items.
[0059] The submission module is used to receive project drafts and submit them for review.
[0060] Thirdly, this application provides a computer storage medium, which adopts the following technical solution:
[0061] A computer storage medium storing a computer program that, when executed by a processor, implements the aforementioned project management method for the environmental impact assessment industry.
[0062] In summary, this application includes the following beneficial technical effects:
[0063] 1. Acquire projects and assign them to the corresponding project leaders. Then, divide the specific projects into several sub-projects based on their implementation details. Generate a project topology diagram based on the implementation status and results of the sub-projects. By analyzing the connection relationships between various topology points and lines in the project topology diagram, as well as the influence of various influencing variables on the continuity of the topology lines, the interrelationships and impact analyses of various parts and links can be realized. This ensures that the environmental impact assessment work maintains a dynamic analysis process and improves the effectiveness of the environmental impact assessment work. Attached Figure Description
[0064] Figure 1 This is a schematic diagram of the overall process of an embodiment of this application;
[0065] Figure 2 This is an example schematic diagram of the project topology in the embodiments of this application. Detailed Implementation
[0066] The following is in conjunction with the appendix Figure 1-2 This application will be described in further detail.
[0067] This application discloses a project management method for the environmental impact assessment industry.
[0068] like Figure 1 As shown, a project management method for the environmental impact assessment industry includes the following steps:
[0069] S100: Obtain project orders and generate corresponding project tasks to be assigned based on the project orders.
[0070] A project order refers to an order received after undertaking project work with enterprises, factories, or other entities that require environmental impact assessments. Once a project order is obtained, corresponding project assignment tasks are generated based on it. These assignment tasks mainly include the project's specific details, requirements, and timelines.
[0071] S200 assigns the tasks to be assigned to the corresponding project manager.
[0072] After receiving the project tasks to be assigned, the tasks are distributed to the corresponding project managers according to certain allocation rules and methods. Each project manager has a corresponding project manager's client, which is generally located on mobile devices such as phones, computers, and tablets as an app, mini-program, or web page.
[0073] Specifically, the following steps are included:
[0074] S210, retrieve project category information from the tasks to be assigned in the project.
[0075] Project classification information should at least include the project's corresponding field, type, and scale. Further details could include project location, company information, etc.
[0076] S220: Obtain the pre-set capability models on the client side of several project managers.
[0077] A competency model is used to characterize the competency information of the corresponding project leader. The competency model can be evaluated by considering the project completion effect, duration, evaluation, results, etc. of each project leader in the past projects. Combined with the project leader's personal wishes, a scoring model is obtained for multiple competency items, including competency in different fields and types of projects, as well as personnel management, project completion timeliness, and other aspects, and scores are given in multiple dimensions.
[0078] S230 compares the project classification information with several capability models to obtain the capability model with the highest matching degree, and then assigns the project classification information to the project manager corresponding to that capability model.
[0079] The project classification information is compared with the scores of various aspects of the competency models corresponding to several project personnel, and the competency model with the highest matching degree is obtained. The specific calculation method of the matching degree can be based on comparing the more important considerations in the project classification information with the scores of the corresponding competency models, and performing multi-angle calculations based on the project personnel's experience in different fields, processing cycles, etc., so as to obtain a more accurate and reasonable matching degree calculation result.
[0080] When several capability models with the same degree of matching appear after comparison, and these capability models have the highest degree of matching, the selection can be made based on the number of projects currently managed by the project personnel corresponding to these capability models. For example, if some project personnel currently have a large number of projects to handle, their workload is large, and the processing time and efficiency for new projects may not be guaranteed. In this case, the project can be assigned to project personnel who currently have fewer projects to manage.
[0081] S300: Obtain contract signing information and generate several project sub-items based on the tasks to be assigned corresponding to the contract signing information. The project sub-items include site survey, data collection, status monitoring, and compilation of final drafts.
[0082] Once a project is assigned to a relevant project manager, the initial coordination work is completed. Then, the contract can be signed. After the project is signed, the tasks to be classified are divided into several sub-projects according to the specific details and work content. In other words, a large project is divided into several smaller projects according to different stages and types of project work, and then distributed to the relevant project personnel for corresponding work.
[0083] Project sub-items generally include four components: site survey, data collection, current status monitoring, and final drafting. These encompass all project content from the early, middle, and late stages of the project.
[0084] Site visit: This involves environmental impact assessment (EIA) personnel going to the site to conduct testing, such as collecting information on the water samples to be tested, the surrounding terrain, the distribution of residents, and the location of factories. A site visit typically takes two days.
[0085] Data collection: This can be done through internet searches, collection of materials from archives, or by searching relevant open resources within the Land and Resources Bureau. Data collection typically takes 3 days.
[0086] Current status monitoring: This involves real-time or intermittent monitoring of one or more locations within the current site that have undergone on-site reconnaissance to obtain relatively continuous data, such as changes in water samples, noise levels, and soil conditions. Current status monitoring typically takes about 20 days.
[0087] Compiling the final draft: This involves one or more people compiling and editing all the data obtained from previous site surveys, data collection, and current status monitoring. Compiling the final draft typically takes 5 days.
[0088] S400, Generate a project topology diagram based on several project sub-items. The project topology diagram includes topology points generated from the work results of several project sub-items, and several topology points that meet preset association and influence conditions are connected by topology lines.
[0089] like Figure 1 and Figure 2 As shown, the project topology diagram is used to identify, store, and analyze the correlation and mutual influence among various work results, work influencing factors, and evaluation contents obtained during the implementation of each project sub-item.
[0090] The results of project sub-items include whether water samples meet standards, resident distribution, surrounding topography, and other information obtained from collected data, as well as changes in data obtained from current status monitoring. In other words, the content of topological points is diverse, containing both static and dynamic information. Any content related to the environmental impact assessment and that has an impact on and is relevant to subsequent project implementation steps can be used as a topological point.
[0091] The project topology diagram is used to analyze the degree of linkage between various steps in the actual implementation of the project. The existence of corresponding topological lines between various topological points is used to determine the degree of correlation and influence between different topological points. Based on the connection and combination relationship between various topological points and topological lines in the topology diagram after the environmental impact assessment, the final environmental impact assessment result of the project is analyzed.
[0092] Specifically, the following steps are included:
[0093] S410 generates the total topology points based on the project order.
[0094] The overall topology point serves as the base point of the entire topology diagram. Only when this base point, i.e., the project order, exists can other subsequent topology points have a basis for connection and influence. Generally speaking, the overall project point is represented in the form of "XX Company Reservoir Environmental Impact Assessment Project" or "XX Factory Coal-to-Natural Gas Project".
[0095] S420, based on the results of the site survey, generate several first-factor topology points. These first-factor topology points include several endpoints, and the first endpoints on these first-factor topology points are all connected to the total topology point.
[0096] The results of the on-site survey include at least water samples, topography, population distribution, and factory distribution around the site. The content of the first factor topology points generated from this can be: "Water sample parameters: XX, qualified", "Forestry distributed in the XX direction", "Residential area exists in the XX direction within the XX range", etc. The specific content can be changed according to the actual situation, as long as the overall subject of the first factor topology points revolves around the factors that affect the final environmental impact assessment results.
[0097] The first factor topology point includes several endpoints. An endpoint is a port used to connect several first factor topology points or between a first factor topology point and other subsequent topology points via topology lines. The number of endpoints on each different topology point can be one or more.
[0098] S430: Based on the results of the on-site survey, obtain the data collection task, collect the corresponding data according to the data collection task, and generate the first influencing variable based on the data collection results.
[0099] Following a site survey, several survey results will be obtained. Some of these results may be disputed, or some may require support from professional data. Furthermore, the specific implementation standards for some survey items may vary depending on the region and field. In such cases, it is necessary to modify or support the preliminary results of the site survey with relevant data. Therefore, after data collection, a first influencing variable is generated based on the obtained data. This influencing variable can modify or verify the information results of the associated first factor topological point.
[0100] S440, substitute the first influencing variable into the first factor topology point respectively, and determine whether several first factor topology points need to be updated.
[0101] If the preliminary survey results of some first-factor topological points may be found to need to be updated, improved, or corrected after data collection, then by substituting the first influencing variable into the first-factor topological points, it can be determined whether the first-factor topological points need to be updated.
[0102] S450, if no update is required, a second factor topology point is generated, and the first endpoint of the second factor topology point is connected to the second endpoint of the first factor topology point to generate a topology line; if an update is required, a second factor topology point is generated, and a blocking monitoring valve is set between the first endpoint of the second factor topology point and the second endpoint of the first factor topology point.
[0103] If no update is needed, it means that the first influencing variable has a small or negligible impact on the first factor topological point, and it will not affect the first factor topological point. In this case, the corresponding second factor topological point is generated based on the association between the first influencing variable and different first factor topological points, and connected by topological lines. The connection by topological lines indicates that a balance has been achieved between the first factor topological point and the second factor topological point, and the environmental impact assessment results will not be affected by the first factor topological point and the second factor topological point that have been connected.
[0104] If an update is required, it indicates that the first influencing variable has a significant impact on the first factor topological point, potentially affecting its information through numerical changes, result modifications, content updates, etc. A second factor topological point will then be generated accordingly. However, because the first influencing variable affects the first factor topological point, a balance cannot be achieved between the two topological points; in other words, there is an entanglement of influence between them. Therefore, a blocking monitoring valve needs to be set between the two topological points. This valve blocks the connection between the two topological points and restores the connection when preset conditions are met. Meeting the preset conditions means that after the information on the first factor topological point is updated, if the influence of the first influencing variable on the first factor topological point decreases sufficiently, a certain balance will be reached, and the blocking monitoring valve can then restore the connection between the two topological points.
[0105] S460, a second influencing variable is generated based on the results of current status monitoring.
[0106] Similarly, a second influencing variable is generated based on the results of the current status monitoring. It is important to note that current status monitoring differs from data collection. Data collection is a concentrated effort, completed within a predetermined 3-day period, and in most cases, no further data collection is conducted. In contrast, current status monitoring involves continuous monitoring of relevant locations, either in real-time or intermittently, over a period of approximately 20 days. Therefore, the second influencing variable is characterized by its continuity and normality compared to the first influencing variable. As various situations arise and values change during current status monitoring, the second influencing variable will continuously change accordingly.
[0107] S470, substitute the second influencing variable into the first factor topology points respectively, and determine whether several first factor topology points need to be updated.
[0108] S480, if no update is required, a third factor topology point is generated, and the first endpoint of the third factor topology point is connected to the third endpoint of the first factor topology point to generate a topology line; if an update is required, a third factor topology point is generated, and a blocking monitoring valve is set between the first endpoint of the third factor topology point and the third endpoint of the first factor topology point.
[0109] The process of incorporating the second influencing variable into the first factor topological point and generating the corresponding third factor topological point is the same as the process described above for the first and second factor topological points. However, it should be noted that because the second influencing variable will continuously change as various situations occur and its value changes during the current monitoring, the generation of the third factor topological point will continue as the second influencing variable changes. For example, if the water quality index was originally 15, and after a period of monitoring, the water quality index changes to 30, then in addition to the previously generated third factor topological point with an index of 15, a topological point with an index of 30 will also be generated. This allows the entire dynamic monitoring process to be reflected through dynamic changes in the topological map, better demonstrating the correlation and influence between various processes and data.
[0110] The process of substituting the first or second influencing variable into the first factor topology point and generating the corresponding second or third factor topology point includes the following steps:
[0111] S471, obtain the type corresponding to the first factor topological point.
[0112] S472, obtain the information with the highest type correlation between the first influencing variable or the second influencing variable and the topological point of the first factor, and bring the corresponding information into the topological point of the first factor.
[0113] S473, Generate the corresponding second or third factor topological point based on the information with the highest type correlation with the first factor topological point.
[0114] The type of topological point can be classified based on the results of on-site surveys, such as water quality, landform, population distribution, and factory distribution.
[0115] Since the first and second influencing variables need to contain information specific to different types, the topological point of the first factor will be selected when substituted. For example, if the first influencing variable includes the new water quality testing standards for the region, then its type is water quality-related. This information will be substituted into the topological point of the first factor, instead of substituted into the topological point of all influencing variables, thus reducing the workload.
[0116] After generating several second-factor and third-factor topological points, related topological points are selected and connected according to their corresponding type correlation, because changes in the values or information between different types of topological points will not affect the results.
[0117] Furthermore, after generating the second influencing variable based on the results of the current status monitoring, the following steps are also included:
[0118] S491, determine whether there is information in the second influencing variable that is associated with the blocking monitoring valve between the first factor topological point and the second factor topological point.
[0119] S492, if it exists, determine whether the information meets the recovery conditions of the blocking monitoring valve.
[0120] If S493 is met, the blocking monitoring valve will restore the connection between the two topology points.
[0121] Since the second factor topology point is generated based on the collected data, it will not change after the data collection is completed. Similarly, the relationship between the first and second factor topology points will not change. Therefore, the dynamic change of the connection relationship between the two topology points needs to be defined according to the second influencing variable, which may change at any time.
[0122] The recovery conditions depend on the specific types of the first and second factor topological points, which could be numerical conditions, environmental conditions, time conditions, etc. For example, if the information at the first factor topological point is a water quality value of 40, while the information at the second factor topological point is that the water quality standard for the region must be lower than 30 according to new regulations, then the first factor topological point does not meet the second factor topological point's requirements, and the two topological points cannot reach an equilibrium. In this case, a blocking monitoring valve will be set. However, if the second influencing variable includes water quality monitoring information, then this water quality-related information from the second influencing variable will be applied to the blocking monitoring valve. If this information indicates that the monitored water quality value has changed to 20, then after applying this influencing variable, the first factor topological point will meet the second factor topological point's requirements, and the corresponding blocking monitoring valve will open, restoring the connection.
[0123] S500 dynamically updates the project topology diagram at preset time intervals based on the work results of several project sub-items, and obtains the corresponding topology results based on the project topology diagram.
[0124] Because the monitoring process for the current status of the project sub-items will continue for a period of time, and the monitoring results may change at any time during this period, the project topology map will be dynamically updated according to different monitoring results in order to obtain richer and more complete environmental impact assessment data and results.
[0125] Specifically, the project topology diagram is dynamically updated based on the work results of several project sub-items, including the following steps:
[0126] S510, acquire the second influencing variable at preset time intervals, where current status monitoring is the process of maintaining real-time monitoring.
[0127] S520, if the second influencing variable changes, the second influencing variable is introduced into the first factor topological point and / or the blocking monitoring valve between the first factor topological point and the second factor topological point;
[0128] S530, the blocking monitoring valve between the first factor topological point and the second factor topological point, and the blocking monitoring valve between the first factor topological point and the third factor topological point are updated according to the second influencing variable.
[0129] Specifically, obtaining the corresponding topology results based on the project topology diagram includes the following steps:
[0130] S540: Obtain information on all blocking monitoring valves in the blocking state in the project topology diagram.
[0131] S550: Based on the information of the blocking monitoring valve, obtain the first factor topology point, the second factor topology point and / or the third factor topology point at both ends of the blocking monitoring valve, and define two adjacent topology points as an abnormal topology point group.
[0132] S560 generates corresponding abnormal causes based on the blocking monitoring valve information and abnormal topology point group.
[0133] Generally speaking, as long as there is a blocking monitoring valve in a blocking state, it can be considered that the information on at least one of the topological points at both ends of the blocking monitoring valve cannot reach a balance. Then, the two adjacent topological points of the first factor topological point and the second factor topological point and / or the third factor topological point at both ends of the blocking monitoring valve are defined as an abnormal topological point group.
[0134] The reason for choosing topological points at both ends instead of those with influence is that the presence of a blocked monitoring valve indicates an inability to achieve balance. Furthermore, since the topological points at both ends are interconnected and mutually influential, selecting topological points at both ends makes the subsequent result processing and analysis more accurate and intuitive.
[0135] Specifically, the following steps are included:
[0136] S561, retrieve historical project exception cases.
[0137] Historical project anomaly cases are characterized by anomaly information in previously completed projects, including at least historical anomaly blocking monitoring valve information, historical anomaly topology point groups, and historical anomaly causes.
[0138] S562 generates a corresponding exception record library based on historical project exception cases.
[0139] The exception log database stores exception records that have occurred by different project personnel for different projects.
[0140] S563, the blocking monitoring valve information and abnormal topology point group are brought into the abnormal record database to determine whether there are any historical project abnormal cases with high similarity.
[0141] S564, if it exists, then the historical anomaly cause corresponding to the historical project anomaly case shall be used as the anomaly cause for the blocking monitoring valve information and the anomaly topology point group.
[0142] If S565 does not exist, output an abnormal alarm message and a manual addition option.
[0143] Since it is necessary to obtain the cause of the anomaly through the information of the blocking monitoring valve and the abnormal topology point group, we can compare and analyze the existing information in the anomaly record library. If the anomaly record library contains cases with a high degree of similarity to the blocking monitoring valve and the abnormal topology point group at both ends, it means that this type of problem has occurred in the past. Then, the cause of the problem can be summarized as the historical project is completed, and it can be directly applied when the cause occurs again.
[0144] However, if the anomaly log does not contain highly similar cases, it may mean that the problem has never occurred before. In this case, it is necessary to output an alarm and provide manual addition options so that users can add cases based on the environmental impact assessment results and project progress. After being added, these cases can be stored in the anomaly log as historical project anomaly cases.
[0145] S570 obtains topology results by blocking monitoring valve information, abnormal topology point groups, and abnormal causes.
[0146] S600 generates a project submission draft based on the topology results and the work results of several project sub-items.
[0147] The topology results and the work results of several project sub-items are integrated to obtain the final project submission draft, thereby completing the dynamic environmental impact assessment of the project.
[0148] This application also discloses a project management system for the environmental impact assessment industry, including a project acceptance module, a project manager's interface, a contract signing module, a report preparation module, a processing module, and a submission module, wherein:
[0149] The project acceptance module is used to accept projects and generate project orders;
[0150] The contract signing module is used to sign project contracts and generate corresponding contract signing information;
[0151] The processing module is used to obtain project orders and generate corresponding project tasks to be assigned based on the project orders, and assign the project tasks to the corresponding project managers; it is also used to obtain contract signing information and generate several project sub-items based on the project tasks to be assigned corresponding to the contract signing information.
[0152] The report preparation module is used to carry out projects based on several project sub-items and generate corresponding project sub-item work results. Specifically, the report preparation module includes a site survey module, a data collection module, a current status monitoring module, and a compilation and finalization module.
[0153] The processing module is also used to generate a project topology diagram based on several project sub-items. The project topology diagram includes topology points generated from the work results of several project sub-items, and several topology points that meet the preset association and influence conditions are connected by topology lines. The module dynamically updates the topology diagram at preset time intervals based on the work results of several project sub-items, and obtains the corresponding topology results based on the project topology diagram. The module generates a project submission draft based on the topology results and the work results of several project sub-items.
[0154] The submission module is used to receive project drafts and submit them for review.
[0155] This application also discloses a computer storage medium storing a computer program, which, when executed by a processor, implements the aforementioned project management method for the environmental impact assessment industry.
[0156] The implementation principle is as follows:
[0157] Projects are acquired and assigned to corresponding project leaders. Then, based on the specific project implementation details, several project sub-items are divided. Based on the implementation status and results of the project sub-items, a project topology diagram is generated. Through the connection relationships between various topology points and topology lines in the project topology diagram, as well as the influence of various influencing variables on the continuity of topology lines, the interrelationships and influence analyses of various parts and links are realized, so that the environmental impact assessment work can maintain a dynamic analysis process and improve the effectiveness of the environmental impact assessment work.
[0158] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.
Claims
1. A project management method for the environmental impact assessment industry, characterized in that, Includes the following steps: Obtain project orders and generate corresponding project tasks to be assigned based on the project orders; Assign the tasks to be assigned to the corresponding project manager; Obtain contract signing information and generate several project sub-items based on the project tasks to be assigned corresponding to the contract signing information. The project sub-items include site survey, data collection, current status monitoring, and compilation of final drafts. A project topology diagram is generated based on several project sub-items. The project topology diagram includes topology points generated from the work results of several project sub-items, and several topology points that meet preset association and influence conditions are connected by topology lines. The project topology map is dynamically updated at preset time intervals based on the work results of several project sub-items, and the corresponding topology results are obtained based on the project topology map. A draft project for review will be generated based on the topology results and the work results of several project sub-items. The process of generating a project topology map based on several project sub-items, and connecting several topology points that meet preset association and influence conditions through topology lines, includes the following steps: Generate the total project topology points based on the project orders; Based on the results of the on-site survey, several first factor topology points are generated. The results of the on-site survey include at least the surrounding water samples, topography, population distribution, and factory distribution. The several first factor topology points include several endpoints, and the first endpoints of the several first factor topology points are all connected to the total project topology points. Based on the results of the site survey, a data collection task is obtained; corresponding data is collected based on the data collection task; and a first influencing variable is generated based on the data collection results. Substitute the first influencing variable into the first factor topology point respectively, and determine whether several first factor topology points need to be updated; If no update is required, a second factor topology point is generated, and the first endpoint of the second factor topology point is connected to the second endpoint of the first factor topology point to generate a topology line; If an update is required, a second factor topology point is generated, and a blocking monitoring valve is set between the first endpoint of the second factor topology point and the second endpoint of the first factor topology point. The blocking monitoring valve is used to block the connection between the two topology points and restore the connection between the two topology points when a preset condition is met. A second influencing variable is generated based on the results of the current status monitoring. Substitute the second influencing variable into the first factor topology point respectively, and determine whether several first factor topology points need to be updated; If no update is required, a third factor topology point is generated, and the first endpoint of the third factor topology point is connected to the third endpoint of the first factor topology point to generate a topology line; If an update is required, a third factor topology point is generated, and a blocking monitoring valve is set between the first endpoint of the third factor topology point and the third endpoint of the first factor topology point.
2. The project management method for the environmental impact assessment industry according to claim 1, characterized in that: Assigning the tasks to be assigned to the project to the corresponding project manager includes the following steps: Obtain the project classification information from the tasks to be assigned in the project, wherein the project classification information includes at least the field, type, and size of the project; Acquire several pre-set capability models on the project manager's end, wherein the capability models are used to characterize the capability information of the corresponding project manager; The project classification information is compared with several capability models to obtain the capability model with the highest matching degree, and the project classification information is assigned to the project manager corresponding to the capability model.
3. The project management method for the environmental impact assessment industry according to claim 1, characterized in that: Substituting the first or second influencing variable into the first factor topology point and generating the corresponding second or third factor topology point, each step includes the following: Obtain the type corresponding to the first factor topology point; Obtain the information with the highest type correlation between the first or second influencing variable and the topological point of the first factor, and substitute the corresponding information into the topological point of the first factor; Generate the corresponding second or third factor topology point based on the information with the highest type correlation to the first factor topology point.
4. A project management method for the environmental impact assessment industry according to claim 1, characterized in that: After generating the second influencing variable based on the results of the current status monitoring, the following steps are also included: Determine whether there is information in the second influencing variable that is associated with the blocking monitoring valve between the first factor topology point and the second factor topology point; If it exists, determine whether the information meets the recovery conditions of the blocking monitoring valve; If the conditions are met, the blocking monitoring valve will restore the connection between the two topological points.
5. A project management method for the environmental impact assessment industry according to claim 1, characterized in that: The project topology diagram is dynamically updated based on the work results of several project sub-items, including the following steps: The second influencing variable is acquired at preset time intervals, wherein the current status monitoring is a process of maintaining real-time monitoring; If the second influencing variable changes, then the second influencing variable is incorporated into the first factor topology point and / or the blocking monitoring valve between the first factor topology point and the second factor topology point; The blocking monitoring valve between the first factor topology point and the second factor topology point, and the blocking monitoring valve between the first factor topology point and the third factor topology point, are updated according to the second influencing variable.
6. A project management method for the environmental impact assessment industry according to claim 1, characterized in that: Obtaining the corresponding topology results based on the project topology diagram includes the following steps: Obtain information on all blocking monitoring valves in the blocked state in the project topology diagram; Based on the information of the blocking monitoring valve, the first factor topology point, the second factor topology point and / or the third factor topology point at both ends of the blocking monitoring valve are obtained, and two adjacent topology points are defined as an abnormal topology point group. The corresponding cause of the anomaly is generated based on the information of the blocking monitoring valve and the abnormal topology point group. The topology results are obtained by analyzing the blocking monitoring valve information, abnormal topology point groups, and abnormal causes.
7. A project management method for the environmental impact assessment industry according to claim 6, characterized in that: Based on the blocking monitoring valve information and the abnormal topology point group, a corresponding cause of the abnormality is generated, including the following steps: Obtain historical project anomaly cases, which are characterized as case information of anomalies in previously completed projects, including at least historical anomaly blocking monitoring valve information, historical anomaly topology point groups, and historical anomaly causes; Generate a corresponding exception record library based on the aforementioned historical project exception cases; The blocking monitoring valve information and the abnormal topology point group are brought into the abnormal record database to determine whether there are any historical project abnormal cases with high similarity to them. If it exists, the historical anomaly cause corresponding to the historical project anomaly case shall be used as the anomaly cause of the blocking monitoring valve information and the anomaly topology point group; If it does not exist, an abnormal alarm message and a manual addition option will be output. The manual addition option allows the user to manually add the cause of the abnormality based on the blocking monitoring valve information and the abnormal topology point group.
8. A project management system for the environmental impact assessment industry, characterized in that: It includes a project acceptance module, a project manager's interface, a contract signing module, a report preparation module, a processing module, and a submission module. The project acceptance module is used to accept projects and generate project orders; The contract signing module is used to sign project contracts and generate corresponding contract signing information; The processing module is used to obtain the project order, generate corresponding project tasks to be assigned based on the project order, and assign the project tasks to the corresponding project manager; it is also used to obtain the contract signing information and generate several project sub-items based on the project tasks to be assigned corresponding to the contract signing information. The report preparation module is used to carry out projects based on several project sub-items and generate corresponding project sub-item work results. Specifically, the report preparation module includes a site survey module, a data collection module, a current status monitoring module, and a compilation module. The processing module is further configured to generate a project topology map based on several project sub-items, the project topology map including topology points generated from the work results of several project sub-items, and several topology points that meet preset association and influence conditions are connected by topology lines; dynamically update the project topology map according to the work results of several project sub-items at preset time intervals, and obtain corresponding topology results based on the project topology map; and generate a project submission draft based on the topology results and the work results of several project sub-items. The submission module is used to receive project drafts and submit them for review. The process of generating a project topology map based on several project sub-items, and connecting several topology points that meet preset association and influence conditions through topology lines, includes the following steps: Generate the total project topology points based on the project orders; Based on the results of the on-site survey, several first factor topology points are generated. The results of the on-site survey include at least the surrounding water samples, topography, population distribution, and factory distribution. The several first factor topology points include several endpoints, and the first endpoints of the several first factor topology points are all connected to the total project topology points. Based on the results of the site survey, a data collection task is obtained; corresponding data is collected based on the data collection task; and a first influencing variable is generated based on the data collection results. Substitute the first influencing variable into the first factor topology point respectively, and determine whether several first factor topology points need to be updated; If no update is required, a second factor topology point is generated, and the first endpoint of the second factor topology point is connected to the second endpoint of the first factor topology point to generate a topology line; If an update is required, a second factor topology point is generated, and a blocking monitoring valve is set between the first endpoint of the second factor topology point and the second endpoint of the first factor topology point. The blocking monitoring valve is used to block the connection between the two topology points and restore the connection between the two topology points when a preset condition is met. A second influencing variable is generated based on the results of the current status monitoring. Substitute the second influencing variable into the first factor topology point respectively, and determine whether several first factor topology points need to be updated; If no update is required, a third factor topology point is generated, and the first endpoint of the third factor topology point is connected to the third endpoint of the first factor topology point to generate a topology line; If an update is required, a third factor topology point is generated, and a blocking monitoring valve is set between the first endpoint of the third factor topology point and the third endpoint of the first factor topology point.
9. A computer storage medium having a computer program stored thereon, characterized in that, When the computer program is executed by a processor, it implements the project management method for the environmental impact assessment industry as described in any one of claims 1 to 7.