KR102433867B1 - Quantity computation method for steel structure using virtual estimation - Google Patents

Abstract

The present invention relates to a method for calculating a steel frame quantity used in calculating an approximate construction cost of various steel frame structures, wherein a virtual integration database (20) containing the characteristic information for the steel frame structure and a calculation index expressed as a steel frame weight per unit area is constructed so that an optimal calculation index can be derived as the characteristic information of the steel frame structure to be calculated is inputted. Through the present invention, in an electronic data processing quantity calculation of the steel frame structure, an objectivity of the calculation information can be secured by improving a work convenience, a speed, and an accuracy, and simultaneously, minimizing a human factor intervention in deriving a calculation result.

Description

Method of calculating the quantity of steel structures using virtual integration {QUANTITY COMPUTATION METHOD FOR STEEL STRUCTURE USING VIRTUAL ESTIMATION}

The present invention relates to a method for estimating the amount of steel frame used in the calculation of the outline construction cost of various steel structures, and a virtual integration database (20) containing characteristic information on steel structures and a calculation index expressed as steel weight per unit area. ) is built so that the optimal calculation index can be derived as the characteristic information of the steel structure to be calculated is input.

Steel structure is widely used in various industrial structures such as various plant facilities as well as residential or commercial general buildings based on its unique constructability and structural stability. occupies

The plan and design of steel structures, as in other structures, inevitably have variability in the basic outline as well as in the overall detailed composition according to changes in various conditions such as site, cost, purpose of use, and laws and regulations. The steel structure needs to fully reflect not only the function as a single individual structure, but also the interaction with various factors such as the relationship with other facilities constituting the plant, equipment and logistics, etc. can be big

In other words, considering the structure and performance of industrial steel structures as well as their relevance to other facilities, there is great variability in planning and design. Alternatively, the approximate construction cost calculation according to the design must also be repeatedly performed.

The plan or design change of such an industrial steel structure is intended to promote optimal conditions and efficiency for the construction and operation of the industrial facility, but if excessive time is a factor in the plan or design change, the side effect of extending the overall construction period and increasing the construction cost In order to make a quick decision in the establishment of a plan or design, a quick and accurate calculation of the outline construction cost for each plan or design is required.

As is well known, the key factor in the calculation of the rough construction cost of a steel structure is the amount of steel, and in particular, in the situation of changes in the above-mentioned plan or design, where the site and schematic scale are fixed or the extent of change is insignificant, the amount of steel is actually It can be said that the approximate construction cost is determined, and various attempts have been made to quickly and accurately calculate the amount of steel frame in the steel structure.

The conventional method for calculating the quantity of steel frame, including Patent No. 1350297, is a typical expert support system. When the detailed specification of the steel structure to be calculated is entered into a computer program for calculating the quantity of steel, the computer program performs the calculation and the corresponding steel frame quantity is calculated. It is performed in a way that calculates the total amount of steel frame of the structure.

In this prior art, as detailed specifications such as the shape, scale, connection state, and specifications of individual members of the target steel structure are input into the computerized program, a preset formula is applied to these input information to calculate the amount of steel frame. It can be called calculation by calculation, and it requires a highly skilled professional technician to establish and input the specifications of the target steel structure for calculation, which requires considerable work time and manpower.

Therefore, it is impossible to respond promptly in the situation of planning and design changes that require rapid result derivation, so there is no choice but to limit its applicability. In addition to the time required for derivation, a significant difference was inevitable in terms of accuracy.

In other words, despite the fact that steel frame quantity calculation is carried out through computerized processing instead of manual work, considerable fluctuations in the accuracy and speed of results are inevitable depending on the competency of the operator. that could cause problems.

The present invention was devised in view of the above problems, and in the method for calculating the quantity of steel structures, a virtual integration database 20 containing various types of characteristic information for steel structures and calculation indexes expressed as steel weight per unit area is built, and , the calculation program for calculating the quantity of steel is connected to the virtual integration database 20, and the input step (S10) in which type characteristic information is input to the calculation program, and the calculation index corresponding to the type characteristic information input by the calculation program Virtual integration, characterized in that it consists of an inquiry step (S20) of inquiring and withdrawing from the virtual integration database (20), and a calculation step (S30) of calculating the quantity of steel frames based on the retrieved calculation index and the building-to-land area of the steel structure. This is a method of calculating the quantity of steel structures using

In addition, in the present invention, a multi-stage dendritic structure in which the characteristic information of the same species forms the same stage is given to the type characteristic information recorded in the virtual integration database 20, and the final stage of the dendritic structure is formed as a calculation index, and the inquiry In step S20, the calculation program retrieves the calculation index corresponding to the input type characteristic information from the virtual integration database 20, and the characteristic information of the closest value is selected for each step in the dendritic structure of the characteristic information. This is a method of calculating the quantity of steel structures using virtual integration.

In addition, in the present invention, a multi-stage dendritic structure in which the characteristic information of the same species forms the same stage is given to the type characteristic information recorded in the virtual integration database 20, and the final stage of the dendritic structure is formed as an output index, and the input step In (S10), the type characteristic information is input to the calculation program, and as the calculation program designates a specific step among the characteristic information of the multi-level dendritic structure recorded in the virtual integration database 20, It is a method of calculating the quantity of steel structures using virtual integration, characterized in that characteristic information is merged.

Through the present invention, it is possible to secure the objectivity of the calculation information by improving the work convenience, speed, and accuracy in calculating the computerized quantity of the steel structure, and at the same time, minimizing the intervention of human factors in deriving the calculation result.

In particular, in carrying out projects related to steel structures, it is possible to quickly and accurately perform quantity calculation tasks that are inevitable when changing plans or design changes, as well as deriving objective and precise calculation results regardless of the professionalism and skill level of the workers. do.

In addition, by continuously updating or accumulating various characteristic information of the steel structure used as basic information when calculating the quantity, the calculation precision can be continuously improved as well as the improvement of the structural form or the improvement of the material according to the development of steel structure technology. Since it is possible to quickly and meaningfully reflect this when improving physical properties, a substantial self-modifying function can be given without any change in the syntax or structure of the computer program that performs quantity calculation.

1 is a flow chart of the present invention;
2 is a system configuration diagram for carrying out the present invention;
3 is a configuration diagram of a server-type system for carrying out the present invention;
4 is an on-line system configuration diagram for carrying out the present invention;
5 is an exemplary view of a virtual totalization database of the present invention;
6 is an exemplary view of a computer screen of the present invention;
7 is an exemplary diagram of a characteristic information input method of the present invention;
8 is an explanatory diagram of the dendritic virtual totalization database inquiry method of the present invention
9 is an exemplary view of a computer screen of the present invention to which a mobile terminal is applied;
10 is a flowchart of a proximity characteristic information selection type embodiment of the present invention;
11 is an explanatory diagram of a virtual integration database inquiry method in the embodiment of FIG.
12 is a flowchart of a characteristic information merging embodiment of the present invention;
13 is an explanatory diagram of a virtual integration database inquiry method in the embodiment of FIG. 12

The detailed configuration and execution process of the present invention will be described with reference to the accompanying drawings.

First, FIG. 1 is a flowchart showing a basic execution process of the present invention. As shown, the present invention is a method for calculating the quantity of steel structures performed by a computer 10 mounted program, and the type characteristic information is provided by the calculation program. It starts with an input step (S10).

2 to 4 are block diagrams illustrating the connection relationship between each component of the system for carrying out the present invention. As shown, the system of the present invention is basically a computer 10 and a virtual system connected to the computer 10 It is composed of the integration database 20, and as shown in FIG. 2, the virtual integration database 20 contains multiple types of specification information and a corresponding calculation index (Estimation Index).

In the system for carrying out the present invention, the system of Fig. 2, which is the most basic embodiment of the present invention, is composed of a computer 10 and a virtual totalization database 20, where the computer 10 includes not only a general desktop PC, but also a desired calculation and Various information devices to which a storage function is assigned can be applied, and the storage device of the computer 10 is a program for carrying out the present invention, which will be described later in the inquiry of the virtual integration database 20, the retrieval and operation of necessary information, or other information through the communication network. A calculation program for performing connection with components and information exchange is loaded.

The calculation program mounted on the computer 10 of the present invention is connected to the virtual integration database 20, and in FIGS. 2 to 4, the virtual integration database 20 is expressed as being connected to the computer 10, In the present invention, the virtual integration database 20 is logically connected to the calculation program, and there is no need for the computer 10 and the virtual integration database 20 to be physically separated. A database 20 may be built.

That is, in the virtual integration database 20 in the present invention, if a calculation program mounted on the computer 10 can access the virtual integration database 20 to inquire and retrieve required information, the computer 10 In addition to being able to be built in a storage device, it may take various forms, such as being separately built in another computer 10 or storage in a remote location.

The various connection structures of the virtual integration database 20 of the present invention can be confirmed in FIGS. 3 and 4 in which a plurality of computers 10 are configured in carrying out the present invention, and a plurality of terminal-type computers 10a or clients 3, in which the type computer 10a is connected to the server 10b through an intranet, etc. As in the embodiment, the virtual integration database 20 may be operated in a form connected to the server 10b or constructed in the storage device of the server 10b instead of being built in each end-end computer 10 .

Accordingly, as in FIGS. 2 to 4, the computer 10 for carrying out the present invention provides Internet access information such as a terminal type or client type computer 10a, a wireless network access mobile terminal, as well as a general desktop PC, as shown in FIGS. The device-type computer 10c or the server 10b is covered, and in particular, as in FIGS. 3 and 4, in an embodiment in which the server 10b and a plurality of end-end computers 10 are connected, the above-described calculation program is The present invention may be implemented in a form mounted on the server 10b, and a browser or other dedicated connection program for connection with the server 10b is mounted on the end computer 10.

In the present invention, the various types of characteristic information set for the steel structure to be calculated for the quantity of steel are various types of information indicating the classification, specifications, or design conditions of the steel structure. is specified in such a way that the characteristic information of each type is given to the steel structure in question, and therefore the type characteristic information in the form of an ordered pair finally corresponds to the calculation index expressed as the weight of the steel frame per unit area.

That is, as in FIG. 5 illustrating the virtual integration database 20 of the present invention, various types of characteristic information can be set by the type, span, tier, and various load conditions and materials of the steel structure. In addition, the ordered pair in which these type characteristic information is combined finally corresponds to an Estimation Index, so that the calculation index can be derived as the type characteristic information is selected.

In the drawing of FIG. 5 , each sheet represents the type of the steel structure, and each field indicates the type characteristic information set in detail for the type, and the type or type characteristic information of these steel structures constitute the order pair. 5 is merely a visual illustration of the basic configuration of the virtual integration database 20 of the present invention, and the actual computerized information recording form may be variously modified to reduce storage capacity and secure access efficiency.

As such, in the present invention, a virtual integration database 20 containing various types of characteristic information about steel structures and calculation indices expressed as steel frame weight per unit area is built, and the calculation program for calculating the amount of steel frame is the virtual integration database 20 It is connected to and starts with an input step (S10) in which type characteristic information is input to a calculation program, and FIGS. 6 and 7 are a computer at the time of performing the present invention for a piperack and an equipment structure, respectively. (10) The screen is illustrated.

As illustrated in FIGS. 6 and 7 , in the present invention, as in the left screen of the drawing, the format of the structure to be calculated is selected, and according to the selection of the format, an input screen implemented as in the right screen of the drawing The input step (S10) may be performed in such a way that the type characteristic information is input to the .

Thereafter, as shown in FIGS. 1 and 8, an inquiry step (S20) of inquiring and retrieving a calculation index corresponding to the type characteristic information input by the calculation program from the virtual integration database 20 is performed, and the inquiry step (S20) The present invention is completed by performing the calculation step (S30) in which the steel frame quantity is calculated based on the calculation index drawn from and the building-to-land area of the steel structure.

After all, the present invention can be said to derive the calculation index based on the characteristic information input by the calculation program connected to the virtual integration database 20 by utilizing the established virtual integration database 20, where the virtual integration database ( 20) can be built based on the results of the integration work performed in the past, as well as performing the integration work on the virtual set steel structure in advance, not the existing steel structure or the steel structure for which the actual construction was planned The virtual integration database 20 may be built by utilizing it.

As such, as detailed specifications such as the shape, scale, connection state, and specifications of individual members are inputted into the program one by one, a preset formula is applied to these input information, breaking away from the prior art of simply calculating the quantity of steel frames. By using the pre-built virtual integration database 20 and type characteristic information, the present invention that can dramatically simplify the initial input operation as well as the overall steel frame quantity calculation process is carried out, thereby increasing user convenience and required time for quantity calculation operation This can be greatly reduced.

Through the simplification of the use procedure and input work, the general desktop PC can perform the steel frame quantity calculation work even with a portable information device such as a smart phone as in FIG. In the embodiment of the bar, it is possible to significantly reduce the required computing resources of the user computer 10, so that the application of the above-described portable information device can be performed more easily.

On the other hand, in the present invention, the type characteristic information recorded in the virtual integration database 20 is given a multi-step dendritic structure in which the characteristic information of the same type forms the same phase as in FIGS. 5 and 8, and the dendritic The final stage of the structure is formed as an output index.

The structure system of characteristic information or calculation index illustrated in FIG. 8 consists of a total of three steps, but this is simplified or modeled for easy understanding, and characteristic information constructed with the virtual integration database 20 in the present invention. As illustrated in FIG. 5 , the structural system of the output index may be configured in multiple stages that significantly exceed the steps of FIG. 8 .

As described above, the present invention is carried out by utilizing the pre-built virtual integration database 20, which matches the characteristic information input in the step-by-step input of each characteristic information and the inquiry process of the virtual integration database 20. Characteristic information on the virtual integration database 20 may be insufficient.

That is, in the process of constructing the virtual integration database 20, sufficient integration information is not collected. This can be solved if the accumulation of required information proceeds as the practical application of the present invention is repeated. In order to be able to carry out the present invention even in a partially incomplete state of the integration database 20, as shown in FIGS. 10 and 11 , a method for selecting the closest value for each step was established.

In this proximity characteristic information selection type embodiment of the present invention, in the above-described inquiry step (S20), the calculation program retrieves the calculation index corresponding to the input type characteristic information from the virtual integration database 20, but in FIG. As described above, the characteristic information of the closest value is selected for each step in the dendritic structure of the characteristic information.

In addition, as another form of the insufficiency of the virtual integration database 20 , when the characteristic information of a stage immediately after selectable in a specific stage is single information, a method of merging other characteristic information of the same stage may be applied.

That is, the virtual integration database 20 illustrated in FIGS. 8, 11 and 13 all have the same structure, and in the step STEP3 after the characteristic information S2/C1 in these figures, S3/C11 is the only selectable characteristic information, In fact, it is impossible to secure the reliability of the derived result through subsequent selection or proximity selection unless the characteristic information of the corresponding stage of the calculation target steel structure is completely identical.

Therefore, in the present invention, as in FIGS. 12 and 13 , in the execution of the input step S10 in which the type characteristic information is input to the calculation program, the characteristic information of the multi-step dendritic structure in which the calculation program is recorded in the virtual integration database 20 . By designating a specific stage in the stage, the characteristic information of the stage immediately after each type of characteristic information in the stage was merged to enable the selection of significant characteristic information in the subsequent stage.

That is, when the characteristic information S2/C1 is selected during the execution of the calculation program, the calculation program collects the characteristic information of subsequent steps and merges the characteristic information after the characteristic information S2/C1 into selectable characteristic information. Nevertheless, effective results can be drawn.

10: computer
20: virtual totalization database
S10: input stage
S20: inquiry step
S30: Calculation step

Claims (3)

In the method for calculating the quantity of steel structures,
A calculation program for calculating the amount of steel and constructing the virtual integration database 20 so that the pre-performed steel structure integration work is utilized so that the order pair of various characteristic information about the steel structure and the calculation index expressed as the steel weight per unit area correspond to each other It is connected to the virtual integration database 20,
an input step (S10) of inputting type characteristic information into a calculation program mounted on the computer (10);
a querying step (S20) of inquiring and retrieving a calculation index corresponding to the type characteristic information input by the calculation program mounted on the computer (10) from the virtual integration database (20);
Virtual integration, characterized in that it consists of a calculation step (S30) in which the steel frame quantity is calculated based on the calculation index retrieved by the calculation program mounted on the computer 10 and the building area of the steel structure without inputting the specifications of individual members A method of calculating the quantity of steel structures used.
The method according to claim 1,
The type characteristic information recorded in the virtual integration database 20 is given a multi-level dendritic structure in which characteristic information of the same species forms the same stage, and the final stage of the dendritic structure is formed as a calculation index;
In the inquiry step (S20), the calculation program mounted on the computer 10 retrieves the calculation index corresponding to the input type characteristic information from the virtual integration database 20, but in each step in the dendritic structure of the characteristic information A method for calculating the quantity of steel structures using virtual integration, characterized in that the characteristic information of the closest value is selected.
The method according to claim 1,
The type characteristic information recorded in the virtual integration database 20 is given a multi-level dendritic structure in which characteristic information of the same species forms the same stage, and the final stage of the dendritic structure is formed as a calculation index;
In the input step (S10), the type characteristic information is input to the calculation program mounted on the computer 10, and as the calculation program designates a specific step among the characteristic information of the multi-level dendritic structure recorded in the virtual integration database 20, the step A method for calculating the quantity of steel structures using virtual integration, characterized in that the characteristic information of the immediately following stage for each characteristic information of various types is merged.

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