CN110796435A - BIM-based paperless office management system - Google Patents

Abstract

The invention discloses a BIM-based paperless office management system, which comprises the following steps: s1, uploading the BIM model and the component information to a BIM information management platform; s2, uploading the deepened drawing of the component to a BIM information management platform; s3, binding the deepened drawing of the component with the corresponding BIM model and the component information; s4, logging in a BIM information management platform through the mobile terminal, and looking up a deepened drawing of the component on line; s5, detecting the quality of the component by comparing the information of the actual component with the information of the component in the deepening map; s6, marking the detection result and storing the detection data; and S7, uploading the detection result of the component to a BIM information management platform. The invention realizes the informatization of quality management, improves the efficiency of quality management, reduces the waste of resources such as paper and the like and achieves the purposes of cost reduction and efficiency improvement by effectively combining the quality inspection process and the BIM platform.

Description

BIM-based paperless office management system

Technical Field

The invention belongs to the field of three-dimensional visual BIM model and informatization quality management research and development and application, and particularly relates to a paperless office management system based on BIM.

Background

At present, when a quality inspection department of a factory performs quality inspection on a product, quality inspection data is generally recorded in a form filled by a quality inspector, and the recording mode has a plurality of defects.

Firstly, a large amount of drawings and form files need to be printed, so that a large amount of resources are wasted;

secondly, paper documents are troublesome to file, and the paper documents are easy to lose, damage and the like after long-term storage;

thirdly, when the product quality is in problem, tracing is troublesome, and the file searching efficiency is low;

fourthly, the feedback timeliness of quality problem rectification information is poor, and the information transmission efficiency is low;

fifthly, the quality report and the data need manual statistics, the efficiency is low, and errors or omissions are easy to occur;

and sixthly, various automatic real-time statistical reports are lacked, and the informatization degree is low.

BIM (building Information modeling), namely, the real Information of the simulation structure is simulated through digital Information. The information here includes not only three-dimensional geometric information but also non-geometric information such as building materials, shapes, costs, and progress. The BIM technology becomes a new trend of informatization development of the building industry in the 21 st century, application and management of the whole life cycle of a building can be realized, and building of a BIM model and addition of information are the core and the foundation for realizing advanced application. An Information Management Platform (Information Management Platform) is used as an Information Platform based on BIM model application, and realizes database Management of Information by using a programming technology, thereby realizing digital application in the aspects of quality, progress, cost and the like.

In the prior art, a method for effectively combining quality inspection and a BIM platform does not exist, so that the informatization management of product quality is realized, and therefore, an informatization management system is urgently needed to realize paperless office of a factory.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides a BIM-based paperless office management system, which realizes informatization of quality management, improves the efficiency of quality management, reduces waste of resources such as paper and the like and achieves the purposes of cost reduction and efficiency improvement by effectively combining a quality inspection process and a BIM platform.

In order to achieve the purpose, the invention adopts the technical scheme that:

a BIM-based paperless office management system comprises the following steps:

s1, uploading all BIM models and component information to a BIM information management platform;

s2, uploading the deepened drawings of all the components to a BIM information management platform;

s3, binding the deepening map of each component with the BIM model and the component information corresponding to the component, wherein the deepening map file of each component is named by the number of the component;

s4, logging in a BIM information management platform through the mobile terminal, and looking up a deepened drawing of the component on line;

s5, detecting the quality of the component by comparing the information of the actual component with the information of the component in the deepening map;

s6, marking the detection result and storing the detection data;

and S7, uploading the detection result of the component to a BIM information management platform, and updating the detection information of the component.

Specifically, in step S1, the BIM model includes a plurality of components, and the component information includes geometric information and attribute information of the components; the geometric information comprises shape and size information of the component; the attribute information includes a model number of the member, and material information.

Specifically, in step S2, the method for uploading the deepening map of the component to the BIM information management platform is as follows: converting the deepened drawing of the component into a PDF format file in CAD software, uploading the deepened drawing in the PDF format to a BIM information management platform, converting the deepened drawing in the PDF format into a deepened drawing in a picture format through the BIM information management platform, and then storing the deepened drawing.

Specifically, in step S4, the deepening map of the component is searched by the BIM model or the component number;

the method for searching the component through the BIM model comprises the following steps: determining a BIM (building information modeling) to which a component to be detected belongs, searching the file name of the BIM on a BIM information management platform to find a BIM file, and searching a deepened image file of the component to be detected in the BIM file;

the method for searching the component through the component number comprises the following steps: and directly searching the number of the component to be detected on the BIM information management platform, and finding out the deepened drawing file of the component to be detected through the component number.

Further, the mobile terminal comprises a tablet computer.

Specifically, in step S5, the method for detecting the quality of the member is as follows: and measuring the size of the component to be detected by using the detection tool, comparing the size information of the component in the deepened drawing with the size information of the actual component obtained by measurement, and judging whether the component is qualified.

Specifically, in step S6, the marker detection includes: marking the measured dimension data on the component, and marking the dimension deviation data on the component; if the size deviation data exceeds the standard, marking a repair mark on the component; saving the detection data includes: recording deviation data, filling in inspection date, name of quality inspector and name of person in charge on BIM information management platform; for a failed component product, the information of "question type" and "question description" needs to be marked.

Specifically, in step S7, the component list in the BIM information management platform includes: a component non-inspection list, a component inspection non-qualified list, and a component inspection qualified list; the method for uploading the detection result to the BIM information management platform comprises the following steps: according to the detection result in the step S6, component files that are qualified for detection are uploaded to a component detection qualified list, component files that are not qualified for detection are uploaded to a component detection unqualified list, and detected component files in the component non-detection list are removed.

Further, after the quality inspection is finished, a quality inspection supervisor can check the quality inspection records and detection data of quality inspection personnel through the BIM platform and derive related quality data (quality report) according to actual requirements.

Furthermore, the BIM platform can perform classified statistics on the quality inspection qualified rate of a factory, the unqualified types and the quantity of the factory in real time, perform statistics on the quality inspection quantity by day in months, and simultaneously perform accurate statistics on the engineering quality conditions of different teams and groups.

Compared with the prior art, the invention has the beneficial effects that:

(1) by recording quality detection data on line, a large amount of paper resources are saved, and meanwhile, the cost is reduced;

(2) quality inspection data are stored on the BIM information management platform, so that the data are not easy to lose and damage and can be stored for a long time;

(3) the product tracing efficiency is high, when the product quality is in problem, the quality inspection data of the component can be quickly searched according to the component number of the product, and the reason of the problem can be searched;

(4) the feedback timeliness of the quality problem correction information is high, and the transmission efficiency is high by transmitting the problem correction information on line;

(5) the quality report is automatically generated, the efficiency is high, errors are not easy to occur, and the informatization degree is high.

Drawings

Fig. 1 is a schematic block diagram of an application flow of a BIM-based paperless office management system according to the present invention.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, the present embodiment provides a BIM-based paperless office management system, where an operation flow of the management system includes the following steps:

s1, uploading all BIM models and component information to a BIM information management platform;

s2, uploading the deepened drawings of all the components to a BIM information management platform;

s3, binding the deepening map of each component with the BIM model and the component information corresponding to the component, wherein the deepening map file of each component is named by the number of the component;

s4, logging in a BIM information management platform through the mobile terminal, and looking up a deepened drawing of the component on line;

s5, detecting the quality of the component by comparing the information of the actual component with the information of the component in the deepening map;

s6, marking the detection result and storing the detection data;

and S7, uploading the detection result of the component to a BIM information management platform.

Specifically, in step S1, the BIM model includes a plurality of components, and the component information includes geometric information and attribute information of the components; the geometric information comprises shape and size information of the component; the attribute information includes a model number of the member, and material information.

Specifically, in step S2, the method for uploading the deepening map of the component to the BIM information management platform is as follows: converting the deepened drawing of the component into a PDF format file in CAD software, uploading the deepened drawing in the PDF format to a BIM information management platform, converting the deepened drawing in the PDF format into a deepened drawing in a picture format through the BIM information management platform, and then storing the deepened drawing.

Specifically, in step S4, the deepening map of the component is searched by the BIM model or the component number;

the method for searching the component through the BIM model comprises the following steps: determining a BIM (building information modeling) to which a component to be detected belongs, searching the file name of the BIM on a BIM information management platform to find a BIM file, and searching a deepened image file of the component to be detected in the BIM file;

the method for searching the component through the component number comprises the following steps: and directly searching the number of the component to be detected on the BIM information management platform, and finding out the deepened drawing file of the component to be detected through the component number.

Further, the mobile terminal comprises a tablet computer, and in the practical application process, the mobile terminal can adopt industrial PAD.

Specifically, in step S5, the method for detecting the quality of the member is as follows: and measuring the size of the component to be detected by using the detection tool, comparing the size information of the component in the deepened drawing with the size information of the actual component obtained by measurement, and judging whether the component is qualified.

Specifically, in step S6, the marker detection includes: marking the measured dimension data on the component, and marking the dimension deviation data on the component; if the size deviation data exceeds the standard, marking a repair mark on the component; saving the detection data includes: recording deviation data, filling in inspection date, name of quality inspector and name of person in charge on BIM information management platform; for a failed component product, the information of "question type" and "question description" needs to be marked.

Specifically, in step S7, the component list in the BIM information management platform includes: a component non-inspection list, a component inspection non-qualified list, and a component inspection qualified list; the method for uploading the detection result to the BIM information management platform comprises the following steps: according to the detection result in the step S6, component files that are qualified for detection are uploaded to a component detection qualified list, component files that are not qualified for detection are uploaded to a component detection unqualified list, and detected component files in the component non-detection list are removed.

When the management system of the embodiment is applied, firstly, a quality inspector logs in a special account number of the quality inspector through a tablet computer, enters a BIM information management platform and enters a component list interface; then adding a list of the members to be detected, wherein the members to be detected can be found in a manner of directly searching member numbers; opening a deepened drawing of the component, detecting the size of the actual component through a detection tool, marking the detected size data on the component, and judging whether the size of the component is qualified; then recording deviation data, filling in inspection date, name of quality inspector and name of person in charge on BIM platform; for unqualified component products, the information of 'problem type' and 'problem description' needs to be marked; finally, the BIM platform automatically refreshes the detection information of the component and divides the component and the detection data thereof into corresponding component lists; a quality inspection supervisor can check the quality inspection records and the detection data of quality inspection personnel through the BIM platform and derive the related quality data according to the actual requirements. The BIM platform can classify and count the quality inspection qualification rate of a factory in real time, count unqualified types and quantity, count quality inspection quantity by day by month, and accurately count the engineering quality conditions of different teams and groups.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. A BIM-based paperless office management system is characterized in that the operation flow of the management system comprises the following steps:

s1, uploading all BIM models and component information to a BIM information management platform;

s2, uploading the deepened drawings of all the components to a BIM information management platform;

s3, binding the deepening map of each component with the BIM model and the component information corresponding to the component, wherein the deepening map file of each component is named by the number of the component;

s4, logging in a BIM information management platform through the mobile terminal, and looking up a deepened drawing of the component on line;

s5, detecting the quality of the component by comparing the information of the actual component with the information of the component in the deepening map;

s6, marking the detection result and storing the detection data;

and S7, uploading the detection result of the component to a BIM information management platform.

2. The BIM-based paperless office management system of claim 1, wherein in step S1, the BIM model comprises a plurality of building blocks, the building block information comprises geometrical information and attribute information of the building blocks; the geometric information comprises shape and size information of the component; the attribute information includes a model number of the member, and material information.

3. The BIM-based paperless office management system of claim 1, wherein in step S2, the method for uploading the deepened drawings of the components to the BIM information management platform comprises: converting the deepened drawing of the component into a PDF format file in CAD software, uploading the deepened drawing in the PDF format to a BIM information management platform, converting the deepened drawing in the PDF format into a deepened drawing in a picture format through the BIM information management platform, and then storing the deepened drawing.

4. The BIM-based paperless office management system of claim 1, wherein in step S4, the deepening map of the building block is searched by BIM model or building block number;

the method for searching the component through the BIM model comprises the following steps: determining a BIM (building information modeling) to which a component to be detected belongs, searching the file name of the BIM on a BIM information management platform to find a BIM file, and searching a deepened image file of the component to be detected in the BIM file;

the method for searching the component through the component number comprises the following steps: and directly searching the number of the component to be detected on the BIM information management platform, and finding out the deepened drawing file of the component to be detected through the component number.

5. The BIM-based paperless office management system of claim 1, wherein in step S4, the mobile terminal comprises a tablet computer.

6. The BIM-based paperless office management system of claim 1, wherein in step S5, the quality detection method for the components comprises: and measuring the size of the component to be detected by using the detection tool, comparing the size information of the component in the deepened drawing with the size information of the actual component obtained by measurement, and judging whether the component is qualified.

7. The BIM-based paperless office management system of claim 1, wherein the tag detection in step S6 comprises: marking the measured dimension data on the component, and marking the dimension deviation data on the component; if the size deviation data exceeds the standard, marking a repair mark on the component; saving the detection data includes: recording deviation data, filling in inspection date, name of quality inspector and name of person in charge on BIM information management platform; for a failed component product, the information of "question type" and "question description" needs to be marked.

8. The BIM-based paperless office management system of claim 1, wherein in step S7, the component list in the BIM information management platform comprises: a component non-inspection list, a component inspection non-qualified list, and a component inspection qualified list; the method for uploading the detection result to the BIM information management platform comprises the following steps: according to the detection result in the step S6, component files that are qualified for detection are uploaded to a component detection qualified list, component files that are not qualified for detection are uploaded to a component detection unqualified list, and detected component files in the component non-detection list are removed.