TWM649719U - Engineering management system and server thereof - Google Patents

Abstract

An engineering management system includes at least one electronic device, and a server. The electronic device includes a processing unit, a communication unit, and a display unit. The display unit displays an operating interface, a contract information, and a project goal. The server includes a servo processing unit, a storage unit and a servo communication unit, and the servo communication unit is connected to the communication unit. The servo communication unit receives input requests, the servo processing unit generates contract information and engineering goals, and the storage unit stores the contract information and the engineering goals. The servo communication unit receives query requests, the servo processing unit obtains the corresponding contract information or engineering goals, and the servo communication unit transmits the selected contract information or engineering goals to the electronic device.

Description

Project management system and its server

This invention relates to a management system, in particular to an engineering management system and its server.

When a construction company wins a bid for a project, it needs to fill in a large number of forms and documents based on project-related regulations. When executing a project, information needs to be shared between different geographical locations and team members, which may lead to information loss or confusion. Moreover, these filling tasks are cumbersome, complex and highly repetitive, requiring a lot of labor costs and resources, and the work efficiency is also poor. Furthermore, it is quite inconvenient when searching for information.

In view of this, in some embodiments, the engineering management system includes at least one electronic device and a server. The electronic device includes a processing unit, a communication unit and a display unit. The processing unit is connected to the display unit and the communication unit. The display unit displays the operation interface, contract information and project goals. The operation interface generates input requests or query requests, and the communication unit transmits the input requests or queries. Require. The server includes a servo processing unit, a storage unit and a servo communication unit. The servo processing unit is connected to the storage unit and the servo communication unit, and the servo communication unit is connected to the communication unit. The servo communication unit receives the input request, the servo processing unit generates contract information and engineering goals according to the input request, and the storage unit stores the contract information and engineering goals. The servo communication unit receives the query request, The servo processing unit obtains corresponding contract information or project goals based on the query request, and the servo communication unit transmits the selected contract information or project goals to the electronic device.

In some embodiments, the storage unit includes a price library that stores a plurality of historical price information, and the servo processing unit generates cost analysis results based on the contract information and the historical price information.

In some embodiments, the cost analysis results include discrete values, and the servo processing unit generates discrete values based on the historical price information.

In some embodiments, the operating interface generates project information, the communication unit transmits the project information to the server, and the storage unit stores the project information.

In some embodiments, the storage unit includes a form library, the form library includes form templates, the servo processing unit generates forms based on project information, project goals, contract information and form templates, and the storage unit stores the forms.

In some embodiments, the operating interface generates a supplementary request, the communication unit transmits the supplementary request to the server, and the storage unit stores the supplementary request. The servo processing unit generates a form based on project information, supplementary requirements, project goals, contract information and form templates, and the storage unit stores the form.

In some embodiments, the servo processing unit accumulates the project information and obtains the project progress information. The servo processing unit determines that the project progress information is greater than the progress threshold, and the servo processing unit generates an autonomous inspection notification.

In some embodiments, the form library includes a self-inspection form template, the operation interface generates self-inspection information, the communication unit transmits the self-inspection information to the server, and the storage unit stores the self-inspection information. The servo processing unit generates an independent inspection form based on the project progress information, project goals, contract information, independent inspection information and independent inspection form template, and the storage unit stores the independent inspection form. Check the form.

In some embodiments, the form library includes a control form template, the servo processing unit generates the control form based on project progress information, project goals, contract information, independent inspection information and the control form template, and the storage unit stores the control form.

In some embodiments, the form library includes an estimate valuation form template, the servo processing unit generates the estimate valuation form based on the project progress information, project goals, contract information and the estimate valuation form template, and the storage unit stores the estimate valuation form.

In some embodiments, the servo processing unit generates a progress report based on project progress information, project goals, contract information, and autonomous inspection information. The servo processing unit drives the servo communication unit to transmit the progress report to the electronic device, and the operation interface displays the progress report.

In some embodiments, the servo processing unit sets the access permission of the electronic device according to the permission setting requirements, and the servo processing unit sets the display content of the operation interface according to the access permission.

In some embodiments, the servo processing unit sets the user account of the electronic device according to the human-machine setting request.

In some embodiments, the server of application engineering management responds with corresponding processing results according to the work requirements sent by the electronic device. The server includes a servo communication unit, a storage unit and a servo processing unit. The servo communication unit receives work requests from the electronic device or transmits processing results to the electronic device. The storage unit stores multiple sets of processing results. The servo processing unit is connected to the servo communication unit and the storage unit, and the servo communication unit is connected to the electronic device via a network. The servo processing unit selects the corresponding processing result from the storage unit according to the work requirements, and the servo processing unit drives the servo communication unit to transmit the selected processing result to the electronic device.

In some embodiments, the work requirements are input requirements or query requirements, and the processing results Due to contract information and/or project objectives.

The project management system described can enable team members to easily share files, archives and progress updates, improve collaboration and communication efficiency among team members, and enable team members to understand the progress of the project in a timely manner and take necessary measures. Resolve any delays or deviations, gain a good grasp of the project's financial status, and take timely measures to control costs. Moreover, the project management system enables team members to easily store, share and access project-related files, avoiding problems with file loss or version confusion. The project management system provides an efficient, accurate and reliable project management method to help team members organize, coordinate and execute projects, thereby improving the quality and efficiency of project delivery, improving the management level of the enterprise and enhancing the competitiveness of the enterprise.

100: Engineering management system

1: Electronic devices

11: Processing unit

12: Communication unit

13:Display unit

131: Operation interface

132:Contract information

133: Project goals

2:Server

21:Servo processing unit

22:Storage unit

221: Price library

222:Form library

23:Servo communication unit

31:Input requirements

32: Query requirements

Figure 1 is a schematic diagram of the engineering management system architecture of an embodiment.

FIG. 2 is a schematic diagram of a display unit displaying an operation interface and contract information according to an embodiment.

FIG. 3 is a schematic diagram of a display unit displaying engineering targets according to an embodiment.

FIG. 4 is an operation sequence diagram (1) of the electronic device and the server according to an embodiment.

FIG. 5 is a schematic diagram of a storage unit architecture according to an embodiment.

Figure 6 is a schematic diagram of the cost analysis results of an embodiment.

FIG. 7A is an operation sequence diagram (2) of the electronic device and the server according to an embodiment.

FIG. 7B is an operation timing diagram (3) of the electronic device and the server according to an embodiment.

FIG. 7C is an operation timing diagram (4) of the electronic device and the server according to an embodiment.

FIG. 8A is an operation timing diagram (5) of the electronic device and the server according to an embodiment.

FIG. 8B is an operation timing diagram (6) of the electronic device and the server according to an embodiment.

FIG. 8C is an operation timing diagram (7) of the electronic device and the server according to an embodiment.

FIG. 8D is an operation timing diagram (8) of the electronic device and the server according to an embodiment.

FIG. 9A is an operation timing diagram (9) of the electronic device and the server according to an embodiment.

FIG. 9B is an operation timing diagram (10) of the electronic device and the server according to an embodiment.

FIG. 10 is an operation sequence diagram (11) of the electronic device and the server according to an embodiment.

Figure 11 is a progress diagram of an embodiment.

Please refer to FIG. 1 , which is a schematic architectural diagram of the engineering management system 100 according to this embodiment. The engineering management system 100 includes at least one electronic device 1 and a server 2 . The electronic device 1 is connected to the server 2 via a network, and the network connection can be through a wired Ethernet, a wireless network or a mobile communication technology series protocol (such as GPRS, 3G, 4G, 5G ) any one.

In some embodiments, the electronic device 1 may be a personal computer, a notebook computer, a tablet computer or a mobile device or other related electronic device. The electronic device 1 includes a processing unit 11 , a communication unit 12 and a display unit 13 . The processing unit 11 is connected to the display unit 13 and the communication unit 12 .

The display unit 13 is used to display the operation interface 131 . The display unit 13 may be, but is not limited to, a computer screen or a display signboard. The operation interface 131 can selectively display the project contract, contract information 132 or project targets 133 . Please refer to FIG. 2 and FIG. 3 , which are respectively a schematic diagram of the display unit 13 displaying the operation interface 131 and the contract information 132 , and a schematic diagram of the display unit 13 displaying the project target 133 . The communication unit 12 is connected to the server 2 via a network. The server 2 provides the project contract and corresponding information to the electronic device 1 .

The project contract is the general term for the relevant contract documents of the project case. And in the contract document Including contract information 132, project objectives 133 or a combination thereof. The contract information 132 is the information in the relevant contract documents of the project case. For example, the contract information 132 can be but is not limited to the project name, year, sponsoring agency, design unit, supervision unit, construction manufacturer, winning bid amount (yuan), change amount, total estimated amount, start date, original contract duration, Scheduled completion date, extension of construction period, scheduled completion date after change. Project target 133 is the progress target of each project in the project contract. In some embodiments, the project target 133 may be, but is not limited to, the project and its description, project unit, project quantity, and project unit price.

In some embodiments, the processing unit 11 performs normalization processing on the contract information 132 of the project contract to hierarchically arrange the contract information 132 according to categories or attributes. For example, the processing unit 11 can hierarchize documents according to the items of the project contract (ie, contract information 132 ), so that different contract information 132 can present its contents in different pages in the operation interface 131 . Alternatively, the keywords in the contract information 132 may be marked with a hyper link. The processing unit 11 is used to load and execute program codes. The communication unit 12 is used to send the input request 31 or the query request 32 to the server 2 .

The server 2 includes a servo processing unit 21 , a storage unit 22 and a servo communication unit 23 . Server 2 may be, but is not limited to, a server host or a personal computer. The servo processing unit 21 is connected to the storage unit 22 and the servo communication unit 23 , and the servo communication unit 23 is connected to the communication unit 12 . The servo communication unit 23 is used to transmit the input request 31 , the query request 32 or the operation result to the electronic device 1 . The storage unit 22 is used to store contract information 132, project goals 133 and project programs. The servo processing unit 21 executes the project program. The project program generates corresponding response results according to the received input request 31 and query request 32, such as contract information 132 or project objectives 133.

Server 2 can be set up in the network cloud, or Server 2 can be set up in In the Local Area Network (LAN). The server 2 obtains the operation requirements of the electronic device 1 through the network for functions such as computing data (data) or storing data/information (information), and the aforementioned operations will be described in detail later. The storage unit 22 may be a hard disk, a solid-state drive (SSD), a tape drive, or the like. In some embodiments, the servo processing unit 21 and/or the processing unit 11 may be any of an X86 series processor (CPU, Central Processing Unit), an embedded controller (Embedded controller) or a micro controller (micro controller). .

In order to clearly explain the operation process of the engineering management system 100, please refer to the operation sequence diagram of the electronic device 1 and the server 2 in Figure 4. First, at the beginning of the project, the operator controls the electronic device 1 and connects the electronic device 1 to the server 2 . The following uses the interaction between the electronic device 1 and the server 2 as an explanation. The electronic device 1 receives the loaded project contract (ie input request 31). When the electronic device 1 completes loading, a project contract screen will be generated in the operation interface 131 . For example, the operator can scan a paper project contract and convert it into an electronic file project contract using optical character recognition (OCR) technology. The electronic device 1 sends the input request 31 to the server 2 .

After the electronic device 1 transmits the project contract to the project management system 100, the servo processing unit 21 generates the contract information 132 and the project target 133 according to the format or content contained in the project contract. At the same time, the operator can view the contract information 132 and the project target 133 through the display unit 13, as shown in FIG. 2 and FIG. 3 . The servo processing unit 21 stores the contract information 132 and the project target 133 into the storage unit 22 . After completing the establishment of the contract information 132 and the project target 133 , other operators can query the server 2 for the contract information 132 or the project target 133 through another electronic device 1 . In this way, different electronic devices 1 can achieve the purpose of collaborative operation.

Please continue to refer to FIG. 4 . The operator operates the electronic device 1 and the operation interface 131 , causing the electronic device 1 to generate a query request 32 . The communication unit 12 sends the query request 32 to the servo communication unit 23 . The servo processing unit 21 obtains the corresponding contract information 132 or project target 133 from the storage unit 22 according to the query request 32 . The servo communication unit 23 transmits the selected contract information 132 or project target 133 to the electronic device 1 . The processing unit 11 drives the display unit 13 and displays the contract information 132 or the project target in the display unit 13 (for the display method, please refer to Figures 2 to 3). Accordingly, the operator can confirm the basic information of the project and the required project items.

Please refer to FIG. 5 , which is a schematic structural diagram of the storage unit 22 in this embodiment. The storage unit 22 contains a price library 221. In some embodiments, the price library 221 stores multiple historical price information (not shown). Historical price information includes the historical prices used in previous engineering cases for each project. In some embodiments, the historical price information further includes the manufacturers, origins or combinations thereof corresponding to the historical prices. Before the electronic device 1 sends a cost analysis request to the server 2, the server processing unit 21 will calculate the corresponding project cost based on the contract information 132 and a plurality of historical price information.

Then, the electronic device 1 sends the engineering target 133 to the server 2 . The servo processing unit 21 compares the cost price of the engineering target 133 and the project cost according to the two, and generates a cost analysis result. The servo processing unit 21 generates a display page according to the cost analysis result, so that the electronic device 1 can play the display page of the cost analysis result. In some embodiments, the cost analysis results are displayed on the display unit 13 using the input prices of each project, as shown in FIG. 6 . In some embodiments, the input price of each project is an average price of the historical prices used in previous project cases. The engineering system uses the input price of the engineering project to calculate the cost and profit percentage of each project. The operator can have a good grasp of the financial status of the project. situation and take timely measures to control costs.

In some embodiments, the cost analysis results include discrete values. The servo processing unit 21 generates discrete values based on multiple historical price information (or price ranges). Among them, the discrete value is the discrete change of the historical price of each project. For example, the servo processing unit 21 analyzes the historical prices used in previous project cases and generates discrete values of the corresponding project items. In FIG. 6 , the generated comparison result between the discrete value and the price is displayed on the display unit 13 in gray scale. Different grayscale systems represent discrete values exceeding different thresholds. The lower the discrete value, the lighter the gray scale, and conversely, the higher the discrete value, the darker the gray scale.

Please refer to FIG. 6 . In some embodiments, the display unit 13 displays three groups of project projects, namely project 1, project 2, and project 3. The historical price range of Project 1 is 400 to 401 yuan, while the input price is 401 yuan. Therefore, the discrete value of the input price of project 1 is "low", so the grayscale density presented by project 1 is "light". The historical price range of Project 2 is 20 to 30 yuan, while the input price is 25 yuan. The discrete value of the input price of project 2 belongs to "medium", so the grayscale density presented by project 2 is "medium". Similarly, the historical price range of Project 3 is 1,000 to 3,000 yuan, and the input price is 2,000 yuan. The discrete value of the input price of project 3 is "high", so the grayscale density presented by project 1 is "high". In some embodiments, the aforementioned grayscale densities can be presented in different colors. For example red, yellow, blue or a combination thereof.

In some embodiments, each historical price of each project further includes corresponding attributes. For example, place of origin, manufacturer, etc. The following takes project 3 as an example. Project 3 has a high discrete value, and its corresponding historical price ranges from 1,000 yuan to 3,000 yuan. The historical price of 1,000 yuan corresponds to the origin attribute of China, and the historical price of 2,000 yuan corresponds to the origin attribute of Taiwan. Bay, and the historical price of 3,000 yuan corresponds to the origin attribute of Europe. Accordingly, the operator can judge that the engineering project may contain multiple attributes through the "high" gray level density presented by the engineering project. In addition, taking project 1 as an example, the discrete value of project 1 is low, and its corresponding historical price is 400 yuan to 401 yuan. The historical price of 400 yuan corresponds to the origin attribute of Taiwan, and the historical price of 401 yuan corresponds to the origin attribute of Taiwan. Accordingly, the operator can judge that the project may contain a few attributes through the "low" gray level density presented by the project. In other words, when the discrete value of an item is higher, it means that the item contains more attributes (or specifications). Accordingly, the gray scale density presented by the project can be used to remind the operator whether there are any specification restrictions in this project, and analyze the specifications and costs required for each project.

Please refer to FIG. 7A . The electronic device 1 can record project information through the operation interface 131 and send the project information to the server 2 . Alternatively, the electronic device 1 sends the contract information 132 to the server 2 . The servo processing unit 21 obtains the project name from the contract information 132 and creates relevant tags of the project information. Among them, the project information includes, but is not limited to, today's weather, filling date, manual filling progress (%), construction projects, today's completed quantity, number of workers, usage and quantity of machinery, and pre-construction inspection items. Then, the processing unit 11 drives the communication unit 12 to send the project information to the servo communication unit 23 . After the server 2 receives the project information, the servo processing unit 21 drives the storage unit 22 to store the received project information.

Please refer to FIG. 5 , which is a schematic structural diagram of the storage unit 22 in this embodiment. The storage unit 22 includes a form library 222 . Form library 222 contains form templates (not shown). The servo processing unit 21 calls the form template and fills in the form template according to the project information, the project target 133 and the contract information 132 stored in the storage unit 22 to generate the form. The servo processing unit 21 stores the form into the storage unit 22 . In some embodiments, the form is a construction log.

Referring to FIG. 7B , in some embodiments, when the operator finds that there is a missing information in the form, the operator generates a supplementary request through the operation interface 131 . The processing unit 11 drives the communication unit 12 to send the supplementary request to the servo communication unit 23 . After the server 2 receives the supplementary request, the servo processing unit 21 drives the storage unit 22 to store the received supplementary request. The servo processing unit 21 selects the corresponding form according to the supplementary requirements. The servo processing unit 21 overwrites the supplementary requirements to the selected form. The storage unit 22 stores the overwritten form.

Referring to FIG. 7C , the electronic device 1 sends a query request 32 to the server 2 for querying the construction log. The servo processing unit 21 obtains the form stored in the storage unit 22 according to the query request 32 . The servo processing unit 21 drives the servo communication unit 23 to transmit the form to the electronic device 1 . The servo communication unit 23 sends the form to the communication unit 12 of the electronic device 1 , and the communication unit 12 sends the form to the operation interface 131 and displays it on the display unit 13 .

In some embodiments, please refer to FIG. 8A , the servo processing unit 21 accumulates multiple pieces of project information stored in the storage unit 22 and forms project progress information. The storage unit 22 stores project progress information. The servo processing unit 21 determines that the project progress information is greater than or equal to the progress threshold, and the servo processing unit 21 generates an autonomous inspection notification. Among them, the storage unit 22 stores the project threshold value (not shown). In some embodiments, the servo processing unit 21 accumulates project information of each project to form project progress information of each project.

Taking the project target 133 as an example, the operator can use the electronic device 1 to operate the operation interface 131 and generate project information after each project is completed. Then, the processing unit 11 drives the communication unit 12 to send the project information to the servo communication unit 23 . After the server 2 receives the project information, the servo processing unit 21 drives the storage unit 22 to store the received project information. The servo processing unit 21 performs cumulative calculations of quantities based on multiple pieces of project information, and the cumulative result of the project information is For project progress information.

When the project progress information is greater than or equal to the progress threshold, an autonomous inspection notification will be generated. In some embodiments, the servo communication unit 23 sends the self-check notification to the communication unit 12 of the electronic device 1 , and the communication unit 12 sends the self-check notification to the operation interface 131 and displays it on the display unit 13 . In other embodiments, the electronic device 1 further includes a warning unit (not shown). The servo communication unit 23 sends a self-inspection notification to the warning unit of the electronic device 1. The warning unit emits a sound or flashes to remind the operator.

The form library 222 further includes independent inspection form templates, control form templates, estimation and pricing form templates or combinations thereof. The self-inspection form template is used to generate self-inspection forms. Control form templates are used to generate control forms. The estimation and valuation form template is used to generate the estimation and valuation form. The following describes the independent inspection form template, control form template, and estimation and pricing form template respectively. The following first explains the process for the operator to create an autonomous inspection form. Referring to FIG. 8B , the operator operates the operation interface 131 and calls the self-inspection form template to cause the server 2 to generate self-inspection information. Among them, the self-inspection form includes multiple pieces of self-inspection information. Self-inspection information can be, but is not limited to, serial number, self-inspection type, self-inspection type, inspection date, inspection location, contractor, third-party vendor, inspection time, inspection photos, inspection items, and missing fields.

First, the processing unit 11 drives the communication unit 12 to send the self-inspection information to the servo communication unit 23 . After the server 2 receives the autonomous inspection information, the storage unit 22 stores the received autonomous inspection information. Next, the servo processing unit 21 generates an autonomous inspection form based on the project target 133, the corresponding project progress information, the contract information 132, the autonomous inspection information and the autonomous inspection form template. The storage unit 22 stores the autonomous inspection form.

Please refer to FIG. 8C . In some embodiments, if the operator finds that there is missing information in the generated autonomous inspection form, the operator operates the electronic device 1 to cause the communication unit 12 to send the supplementary request to the server 2 . The servo processing unit 21 updates the number or content of fields of the autonomous inspection form according to the supplementary requirements.

Please refer to FIG. 8D , the electronic device 1 sends a query request 32 to the server 2 for querying the autonomous inspection form. The servo processing unit 21 obtains the autonomous inspection form stored in the storage unit 22 according to the query request 32 . The servo processing unit 21 drives the servo communication unit 23 to transmit the main inspection form to the electronic device 1 . The servo communication unit 23 sends the self-check form to the communication unit 12 of the electronic device 1 , and the communication unit 12 sends the self-check form to the operation interface 131 and displays it on the display unit 13 .

Next, the process for the operator to create a control form will be described. Referring to FIG. 9A , the servo processing unit 21 generates a control form based on the project progress information, the project target 133 , the contract information 132 , the self-inspection information and the control form template. The storage unit 22 stores the control form. In some embodiments, if the operator finds that there is missing information in the generated control form, the operator operates the electronic device 1 to cause the communication unit 12 to send the supplementary request to the server 2 . The servo processing unit 21 updates the number or content of fields of the control form according to the supplementary requirements.

Please refer to FIG. 9B . In some embodiments, the electronic device 1 sends a query request 32 for querying the control form to the server 2 . The servo processing unit 21 obtains the control form stored in the storage unit 22 according to the query request 32 . The servo processing unit 21 drives the servo communication unit 23 to transmit the control form to the electronic device 1 . The servo communication unit 23 sends the control form to the communication unit 12 of the electronic device 1 , and the communication unit 12 sends the control form to the operation interface 131 and displays it on the display unit 13 .

Next, the creation process of the estimation and pricing form by the operator is explained. Referring to FIG. 9A , the servo processing unit 21 generates an estimate and estimate form based on the project progress information, the project target 133 , the contract information 132 and the estimate and estimate form template. The storage unit 22 stores the estimate valuation form. In some embodiments, if the operator finds that there is missing information in the generated estimate pricing form, the operator operates the electronic device 1 to cause the communication unit 12 to send the supplementary request to the server 2 . The servo processing unit 21 updates the number or content of fields of the estimation valuation form according to the supplementary requirements.

Please refer to FIG. 9B . In some embodiments, the electronic device 1 sends a query request 32 to the server 2 for querying the estimation and pricing form. The servo processing unit 21 obtains the estimate pricing form stored in the storage unit 22 according to the query request 32 . The servo processing unit 21 drives the servo communication unit 23 to transmit the estimation and pricing form to the electronic device 1 . The servo communication unit 23 sends the estimation and pricing form to the communication unit 12 of the electronic device 1 , and the communication unit 12 sends the estimation and pricing form to the operation interface 131 and displays it on the display unit 13 .

Please refer to FIG. 10 . In some embodiments, the servo processing unit 21 generates a progress report based on project progress information, project goals 133 , contract information 132 and autonomous inspection information. The servo processing unit 21 drives the servo communication unit 23 to transmit the progress report to The electronic device 1 is displayed on the display unit 13 . In some embodiments, the servo communication unit 23 transmits the progress report to the electronic device 1 . The servo communication unit 23 sends the progress report to the communication unit 12 of the electronic device 1 , and the communication unit 12 sends the progress report to the operation interface 131 and displays it on the display unit 13 .

In some embodiments, the progress report contains basic project information. Basic project information includes, but is not limited to, project name, year, sponsoring agency, design unit, supervision unit, construction manufacturer, winning bid amount (yuan), change amount, total estimated amount, start date, original contract duration, scheduled completion date, extension of construction period, and scheduled completion date after change. In some embodiments, Progress reports also include progress maps and/or project notice boards. Please refer to FIG. 11 , which is a progress diagram of an embodiment. Includes scheduled progress curve and actual progress curve. From this, project managers can keep abreast of the progress of the project and take necessary steps to resolve any delays or deviations.

In some embodiments, the servo processing unit 21 sets the access permission of the electronic device 1 according to the permission setting requirements, and the servo processing unit 21 sets the display content of the operation interface 131 according to the access permission.

In some embodiments, the servo processing unit 21 sets the user account of the electronic device 1 according to the human-machine setting request.

The project management system of any embodiment can enable team members to easily share files, archives and progress updates, improve collaboration and communication efficiency among team members, and enable team members to understand the progress of the project in a timely manner and take necessary actions. measures to resolve any delays or discrepancies, and also have a good grasp of the financial status of the project and take timely measures to control costs. Moreover, the project management system of any embodiment enables team members to easily store, share and access project-related files, avoiding problems of file loss or version confusion. The engineering management system of any embodiment provides an efficient, accurate and reliable project management method to help team members organize, coordinate and execute projects, thereby improving the quality and efficiency of project delivery, improving the management level of the enterprise and enhancing the competitiveness of the enterprise. .

100: Engineering management system

1: Electronic devices

11: Processing unit

12: Communication unit

13:Display unit

2:Server

21:Servo processing unit

22:Storage unit

23:Servo communication unit

31:Input requirements

32: Query requirements

Claims (15)

An engineering management system including: At least one electronic device includes a processing unit, a communication unit and a display unit. The processing unit is connected to the display unit and the communication unit. The display unit displays an operation interface, a contract information and a project target. The operation interface An input request or an inquiry request is generated, and the communication unit transmits the input request or the inquiry request; and A server includes a servo processing unit, a storage unit and a servo communication unit. The servo processing unit is connected to the storage unit and the servo communication unit. The servo communication unit is connected to the communication unit; the servo communication unit receives the Input request or the query request; the server processing unit generates the contract information and the project target based on the input request, and the storage unit stores the contract information and the project target; the server processing unit obtains the corresponding contract information based on the query request or the project target, the servo communication unit transmits the selected contract information or the project target to the electronic device. The project management system of claim 1, wherein the storage unit includes a price library that stores a plurality of historical price information, and the server processing unit generates a cost analysis result based on the contract information and the historical price information. The engineering management system of claim 2, wherein the cost analysis result includes a discrete value, and the servo processing unit generates the discrete value based on the historical price information. The project management system as described in claim 1, wherein the operation interface generates project information, the communication unit transmits the project information to the server, and the storage unit stores the project information. The project management system as described in claim 4, wherein the storage unit includes a form library, the form library includes a form template, and the service processing unit generates a form based on the project information, the project target, the contract information and the form template. Form, the storage unit stores the form. The project management system as described in claim 5, wherein the operation interface generates a supplementary request, the communication unit transmits the supplementary request to the server, and the storage unit stores the supplementary request; the servo processing unit based on the project information, the The supplementary requirements, the project target, the contract information and the form template generate the form, and the storage unit stores the form. The project management system as described in claim 5, wherein the servo processing unit accumulates the project information and obtains a project progress information, the servo processing unit determines that the project progress information is greater than a progress threshold, and the servo processing unit generates an autonomous Check for notifications. The project management system as described in request item 7, wherein the form library includes an autonomous inspection form template, the operation interface generates an autonomous inspection information, the communication unit sends the autonomous inspection information to the server, and the storage unit stores the autonomous inspection information. Inspection information; the servo processing unit generates an independent inspection form based on the project progress information, the project target, the contract information, the independent inspection information and the independent inspection form template, and the storage unit stores the independent inspection form. The project management system as described in claim 8, wherein the form library includes a control form template, and the server processing unit generates a control form template based on the project progress information, the project target, the contract information, the independent inspection information and the control form template. Control form, the storage unit stores the control form. The project management system as described in claim 7, wherein the form library includes an estimate and price form template, and the servo processing unit generates an estimate and price form template based on the project progress information, the project target, the contract information and the estimate and price form template. The estimation and valuation form is stored in the storage unit. The project management system as described in claim 8, wherein the servo processing unit generates a progress report based on the project progress information, the project target, the contract information and the independent inspection information, and the servo processing unit drives the servo communication unit to transmit the The progress report is sent to the electronic device, and the operation interface displays the progress report. The engineering management system of claim 1, wherein the servo processing unit sets an access authority of the electronic device according to an authority setting requirement, and the servo processing unit sets the display content of the operation interface according to the access authority. The project management system of claim 1, wherein the servo processing unit sets a user account of the electronic device according to a human-machine setting request. A server for application engineering management that responds with a corresponding processing result based on a work request sent by an electronic device. The server includes: A servo communication unit receives the work request from the electronic device or transmits the processing result to the electronic device; A storage unit to store multiple sets of processing results; and A servo processing unit is connected to the servo communication unit and the storage unit. The servo communication unit is connected to the electronic device via a network. The servo processing unit selects the corresponding processing result from the storage unit according to the work requirement. The servo processing unit The processing unit drives the servo communication unit to transmit the selected processing result to the electronic device. As claimed in claim 14, the application project management server, wherein the work request is an input request or a query request, and the processing result is a contract information and/or a project goal.