JP2004110264A - Design system for aseismic reinforcing work, method for guaranteeing aseismic reinforcement, diagnostic method for aseismic property, method for designing aseismic reinforcing work, and method for making written estimate for aseismic reinforcing work - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for guaranteeing aseismic reinforcing work by performing diagnosis on aseismic properties and the designing of construction work with high reliability without an individual difference among diagnosticians or designers, automatically creating estimates for them, and linking insurances about diagnosis on aseismic properties, aseismic reinforcing work, and earthquakes. <P>SOLUTION: Article data of an existing housing are inputted to pieces of aseismic property diagnosis/construction work design software 22, 32, 42 and 52 incorporated into respective terminal devices 20, 30, 40 and 50. The data are computed and compared with predetermined criteria to determine the aseismic properties of the existing housing. If the housing needs aseismic reinforcing, data on members such as bearing walls to be added to the input article data are inputted and the aseismic properties are determined using a similar method so as to design aseismic reinforcing work to meet a grade about a predetermined aseismic property. When the designed aseismic reinforcing work has been done, an earthquake insurance favored according to the grade is given to guarantee the work. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention provides a seismic retrofitting design system for designing seismic retrofitting works by grade for seismic retrofitting, a seismic retrofitting design method using the same, and a seismic retrofitting diagnostic method used therefor. The method, seismic retrofitting design method and seismic retrofitting work estimate creation method.
[0002]
[Prior art]
Interest in the earthquake has increased since the Great Hanshin Earthquake, and various disaster prevention and earthquake countermeasures are being taken by government agencies such as government agencies. For example, the so-called seismic retrofit improvement promotion law was enacted in 1995, and it is encouraged to actively promote seismic assessment and rehabilitation. In addition, the Building Standards Law was revised in 2000 to include the mandatory use of ground surveys, the specification of structural materials and joints and connections, the calculation of the balance of the arrangement of load-bearing walls, and the introduction of the so-called eccentricity calculation. In 2001, the Ministry of Land, Infrastructure, Transport and Tourism published a guideline for the evaluation of seismic rating for determining the danger of collapse of existing houses, and a performance display system that incorporates the seismic rating in the so-called Quality Assurance Law has started.
Buildings and wooden houses in recent years have been constructed in accordance with these laws and standards, and have been constructed so as to maintain sufficient strength to withstand earthquakes even when a large earthquake arrives. However, many existing wooden houses, which have been built for some time, have problems with seismic resistance, which calls for the need for seismic reinforcement.
Generally, architects, contractors, construction contractors, etc., design and carry out seismic reinforcement work independently based on their respective knowledge and experience.
[0003]
[Problems to be solved by the invention]
However, general owners of existing houses do not know what seismic retrofitting work is necessary even if they know that seismic retrofitting is necessary. They look for shops and contractors, consult on construction details and construction costs, request quotes, and trust construction content to place orders.
On the other hand, the architects, contractors, and contractors who have been commissioned to make their own designs and estimates are based on their own judgments. There are differences in construction costs. On the other hand, users had no choice but to trust the proposed construction.
In addition, even if a company conducts seismic diagnosis and seismic reinforcement work, the knowledge and experience of the person in charge of the diagnosis and construction design will cause differences in the diagnosis results, construction details, and construction costs. There may be doubts about gender.
[0004]
The present invention solves these problems, and performs highly reliable seismic diagnosis and construction design that conforms to the Building Standards Law and other various laws and standards, and has no individual differences among diagnosticians and designers. -Based seismic retrofitting design system that can automatically create an estimate for a building and present the results clearly to the customer, as well as the seismic retrofitting diagnostic design method, seismic retrofitting design method, and seismic retrofitting estimate The purpose is to provide a creation method.
Another object of the present invention is to provide a method for assuring seismic reinforcement work in which seismic diagnosis, seismic reinforcement work, and insurance relating to earthquakes are linked.
[0005]
[Means for Solving the Problems]
The seismic retrofitting construction design system of the present invention according to claim 1, wherein one or a plurality of computers and a database are connected by a data bus or a network, and the computer comprises wall data, opening data, and proof strength of an existing house. Seismic diagnosis means for judging the wall volume, wall arrangement balance, column end joints, foundation shape compatibility and seismic performance based on the wall data and column data based on the Building Standard Law, and seismic Construction design means for designing reinforcement work.
According to a second aspect of the present invention, there is provided the seismic retrofitting design system according to the first aspect, further comprising an estimate creating means for creating a construction estimate for the seismic retrofitting work.
According to a third aspect of the present invention, in the seismic retrofitting construction design system according to the first aspect, the database includes customer data that is an owner or resident of an existing house; property data of the existing house; Diagnosis result data determined by the seismic diagnosis means and design data designed by the construction design means are accumulated.
The method for assuring seismic retrofitting of the present invention according to claim 4 includes a step of diagnosing the seismic performance of the existing house, a step of designing the seismic retrofitting work according to the grade of the seismic retrofitting work according to the diagnosis result, The method includes a step of constructing an earthquake-resistant reinforcement work based on a design result, and a step of extracting insurance information on earthquakes having different security contents according to the class after the completion of the earthquake-resistant reinforcement work.
The seismic diagnosis method of the present invention according to claim 5, wherein the step of storing property data of the existing house in the software for seismic diagnosis and construction design, the step of storing the wall position of the existing house, and the opening of the existing house A step of storing a position, a step of storing a type and a magnification of a load-bearing wall of the existing house, a step of storing a pillar position of the existing house, and a step of storing a foundation reinforcement position of the existing house. Determining the wall volume and the wall placement balance based on the data obtained; determining the strength magnification for the seismic performance according to the Building Standard Law; and determining the degree of safety of the placed wall volume against the required amount according to the Building Standard Law And judging the degree of safety of the column end connector with respect to the required amount according to the Building Standards Law.
According to a sixth aspect of the present invention, the seismic retrofitting construction design method of the present invention captures, into a computer, property data, wall positions, opening positions, types and magnifications of bearing walls, column positions, and foundation reinforcing positions input by seismic resistance diagnosis software. Step, a step of storing the type and magnification of the load-bearing wall to be newly added for reinforcement, a step of automatically arranging the load-bearing wall according to a desired reinforcement strength grade, and a position of a column to be added for reinforcement. Memorizing step, memorizing the position of the foundation reinforcement to be added for reinforcement, determining the arrangement balance of the wall and necessary wall amount based on the added load-bearing wall, column, foundation, Determining the strength factor for the seismic performance of the building, determining the degree of safety of the amount of the placed wall against the required amount according to the Building Standard Law, and constructing the column end joint Characterized in that it comprises the step of determining the degree of safety for the required amount of semi-law.
According to a seventh aspect of the present invention, in the seismic retrofitting design method according to the sixth aspect, means for determining whether or not the wall is close to four corners, and determining whether the wall is a blind wall or a wall having an opening. Means for determining the magnitude of the eccentricity due to the addition of the load-bearing wall, wherein the load-bearing wall is added from a wall close to four corners, added to a blind wall, and has an opening. , And is arranged so that the eccentricity is reduced.
According to an eighth aspect of the present invention, in the method for designing a seismic retrofitting construction according to the sixth aspect, the step of storing the type and magnification of the additional load-bearing wall, the step of automatically arranging the load-bearing wall, and the position of the column to be added are performed. In each of the step of storing and the step of storing the position of the foundation reinforcement to be added, the filling rate and the eccentricity of the additional member are calculated and displayed.
According to the ninth aspect of the present invention, there is provided a method for preparing an estimate of seismic retrofitting work according to the sixth aspect of the present invention. Taking the estimated unit price of the related cost and the cost unit price into a computer, calculating the man-hours for the member by the computer, and calculating the estimated amount of the seismic retrofitting work based on the data and the man-hours by the computer And characterized in that:
[0006]
BEST MODE FOR CARRYING OUT THE INVENTION
In the seismic retrofitting construction design system according to the first embodiment of the present invention, one or more terminal devices and a database are connected by a data bus or a network, and the terminal devices include wall data, opening data, and proof stress of an existing house. Based on the wall data and column data, seismic diagnosis means for judging the wall volume, wall arrangement balance, column end joints, conformity of foundation shape and seismic performance based on the Building Standard Law, and seismic It is provided with means for construction design for designing reinforcement work. According to the present embodiment, it is possible to perform highly reliable seismic diagnosis and construction design that conforms to the standards of the Building Standards Law and has no individual differences among diagnosticians and designers.
In the second embodiment of the present invention, the seismic retrofitting construction design system according to the first embodiment further includes estimation creating means for creating a construction estimate of the seismic retrofitting construction. According to the present embodiment, an estimate of the designed seismic retrofitting work can be automatically created.
According to a third embodiment of the present invention, in the seismic retrofitting design system according to the first embodiment, the database includes customer data of the owner or resident of the existing house, property data of the existing house, and seismic diagnosis means. And the design result data by the design of the construction design means are accumulated. According to the present embodiment, it is possible to manage the situation regarding the seismic resistance of an existing house owned by a customer with a computer, and to manage the design of the seismic diagnosis and the seismic reinforcement work with the computer.
The seismic retrofit assurance method according to the fourth embodiment of the present invention diagnoses seismic performance of an existing house, designs seismic retrofitting work according to the grade of seismic retrofitting work according to the diagnosis result, and performs seismic retrofitting work based on the design result. After the completion of the reinforcement work, insurance information on earthquakes with different security contents according to the grade of the earthquake-resistant reinforcement work is extracted. According to the present embodiment, it is possible to propose and execute a series of flows from the seismic resistance diagnosis of the existing house to the construction of the seismic strengthening work requested by the customer and the guarantee after the completion of the work as a pack. Sales activities for customers who are the owners of the products are facilitated, and the customers can clearly understand the contents from the earthquake resistance diagnosis to the guarantee after the completion of the construction. Therefore, the reliability of the seismic retrofitting work can be improved.
The seismic diagnosis method according to the fifth embodiment of the present invention is based on seismic diagnosis / construction design software, which includes property data of existing houses, wall position data, opening position data, type and magnification data of bearing walls, column position data, and foundation data. Reinforcement position data is stored, the amount of walls and the wall placement balance are determined based on the stored data, the strength magnification for seismic performance according to the Building Standards Law, and the degree of safety for the required amount of walls are determined. This is to judge the degree of safety for the required amount of fixtures according to the Building Standards Law. According to the present embodiment, it is possible to perform a highly reliable seismic diagnosis using a computer without any individual differences among diagnosers.
The seismic retrofitting construction design method according to the sixth embodiment of the present invention is based on a method in which property data, wall positions, opening positions, types and magnifications of load-bearing walls, pillar positions, and foundation reinforcing positions input by seismic diagnosis software are used. The type and magnification of the load-bearing wall to be added for reinforcement are stored in this, and this load-bearing wall is automatically arranged according to a desired reinforcing strength class, and the position of a pillar to be added for reinforcement and the position of foundation reinforcement Based on the added load-bearing walls, columns, and foundations, determine the amount of walls, the wall placement balance and the required amount of walls, the strength ratio for seismic performance according to the Building Standards Law, and the building standards of the amount of placed walls The purpose of this study is to determine the degree of safety against the required amount according to the law and the degree of safety against the required amount according to the Building Standard Law of the column end joints. According to the present embodiment, it is possible to use a computer to design a highly reliable seismic retrofitting work with no individual differences among designers.
According to a seventh embodiment of the present invention, in the seismic retrofitting design method according to the sixth embodiment, means for determining whether or not the wall is close to four corners, and whether the wall is a blind wall or a wall having an opening. And a means for determining the magnitude of the eccentricity due to the addition of the load-bearing wall. The load-bearing wall is added from a wall close to the four corners, added to the blind wall, and has an opening. Without being added to the wall, it can be arranged so that the eccentricity is small.
According to an eighth embodiment of the present invention, in the seismic retrofitting construction design method according to the sixth embodiment, a step of storing the type and magnification of the added load-bearing wall, a step of automatically arranging the load-bearing wall, In each of the step of storing the position and the step of storing the position of the foundation reinforcement to be added, the filling rate and the eccentricity of the additional member are automatically calculated and displayed on the screen. According to the present embodiment, each time a load-bearing wall, a column, and a foundation reinforcement are added, the sufficiency and the eccentricity of the additional member can be confirmed, so that the design of the seismic reinforcement work can be efficiently performed. it can.
The method for preparing an estimate of seismic retrofitting work according to the ninth embodiment of the present invention is based on the type, quantity, estimated unit price, cost unit price, and repair required for construction by the seismic retrofitting construction design method described in Embodiment 6. The computer incorporates the estimated unit cost of foundation-related costs and the cost unit price, automatically calculates man-hours for these members, and automatically calculates the estimated amount of seismic retrofitting work based on each data and man-hours. According to the present embodiment, it is possible to calculate the amount of money required for the seismic retrofitting work in conjunction with the design of the seismic retrofitting work and automatically create an estimate.
[0007]
【Example】
Hereinafter, an embodiment of an earthquake-resistant diagnosis system and an earthquake-resistant reinforcement construction system according to the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a system configuration of an earthquake-resistant diagnosis system and an earthquake-resistant reinforcement construction system according to the present invention. The earthquake-resistant diagnosis system and the earthquake-resistant reinforcement construction system are composed of one or more terminal devices 20, 21, 22, and 23 and a database 10, and are connected by a data bus or a network 15. Each of the terminal devices 20, 21, 22, and 23 includes a computer such as a personal computer 24, 25, 26, and 27, and seismic diagnosis / construction design software 28, 29, 30, and 31 incorporated therein. The database 10 stores data of customers who are owners of existing houses and the like and property data, and inputs and outputs earthquake-resistant diagnosis / construction design software 28, 29, 30, and 31 data.
When the earthquake-resistant diagnosis system and the earthquake-resistant reinforcement construction system are configured in one office unit, the database 10 is installed in the office, and each of the terminal devices 20, 21, 22, and 23 is installed in the sales counter unit or the sales office in the office. It is arranged in man units. When the earthquake-resistant diagnosis system and the earthquake-resistant reinforcement construction system are configured on a nationwide scale, the database 10 is installed in a central management center such as a sales headquarters, and each of the terminal devices 20, 21, 22, and 23 is operated by a local sales office. It is arranged in the sales counter unit or salesman unit in the office.
[0008]
Fig. 2 is a flow chart showing the function and operation flow of the seismic reinforcement assurance method using the seismic reinforcement design system according to the present invention. The seismic diagnosis of existing houses, the design and automatic estimation of seismic reinforcement work, and the construction of seismic reinforcement work And the guarantee after the completion of construction.
In step (hereinafter abbreviated as S) 1, when a customer who is an owner of an existing house requests a contractor to conduct a diagnostic investigation on the seismic resistance of an existing wooden house or the like, the contractor uses a computer to perform a predetermined diagnostic program in S2. Diagnosis and judgment of earthquake resistance are performed according to The details of the diagnosis program and the diagnosis determination method will be described later. Based on the result of the diagnosis, it is determined in S3 whether or not the seismic retrofitting is necessary. If it is necessary, the process proceeds to S4 to design the seismic retrofitting work according to the grade of the seismic retrofitting work desired by the customer. This design is linked to the diagnostic program performed in S2 and uses a computer to make use of earthquake-resistant diagnosis and construction design software, taking into account laws and regulations such as the Building Standards Law and seismic retrofitting standards set by contractors independently. It is designed according to the created design program. Details of the design will be described later.
When the specific details of the seismic retrofitting work are determined, the necessary components and work contents for the contents of the seismic retrofitting work are calculated in step S5 according to the estimate creation program installed in the computer in advance, and the reinforcement work is performed for each class relating to the seismic retrofit. Is automatically created. The contents of the reinforcement work and the estimate written in S4 and S5 are proposed to the customer, and the customer decides whether or not to order the work in S6, and if so, which grade is related to earthquake resistance. When ordering the construction, the process proceeds to S7, where the construction contractor performs seismic reinforcement work. When the construction is completed, a seismic standard grade guarantee is issued in S8, and a prescribed guarantee is made according to the grade. Specifically, when taking out the insurance related to the earthquake of a predetermined insurance company, the amount of the insurance money is set according to the grade and the preferential treatment is provided.
[0009]
Next, the procedure of the earthquake resistance diagnosis will be described with reference to FIG. FIG. 3 is a flowchart illustrating the procedure of the earthquake resistance diagnosis according to the present invention. First, when the seismic diagnosis / construction design software installed in the personal computer or the like is started in S11, a screen for the seismic diagnosis is displayed. FIG. 4 shows the displayed startup screen. The start screen 40 includes a plan window 41 for inputting a plan of an existing house to be diagnosed, a mode pallet 42 for designating switching from the input mode to each determination mode, an instruction of necessary functions in each mode, and determination and printing of each item. A command palette 43 for instructing, a decision window 44 for displaying a current decision result for each mode in a digest, a status panel 45 for displaying input instructions in each mode, a tool in which various frequently used functions are registered, and print settings. , A toolbar in which menus such as a default value change and help are registered, and a menu bar 46.
The start screen 40 constitutes a new creation screen for inputting a property to be diagnosed, and inputs property data to the new creation screen in S12. Property data can be input from existing customer data already stored in the earthquake-resistant diagnosis / construction design software, or new customer data can be created. These selections are made by clicking on certain tabs on the toolbar. When importing from existing customer data, the customer data window is opened, the property data is selected, and the property data is read.
[0010]
Next, in step S13, the "property summary" tab of the command palette 43 is clicked to display a property summary screen. FIG. 5 shows a property summary input screen. On the property summary input screen, in addition to the property name and property code, enter dimensions, roof, ground, foundation, joint conditions, etc.
Next, in step S14, the user clicks the "wall box" or "wall line" tab on the command palette 43 to input wall information. FIG. 6 shows the wall input screen. Walls are entered by clicking on the start and end points. In this case, it is not necessary to distinguish between the outer wall and the inner wall, and the room section is automatically recognized. By using the "wall segment", it is possible to input an oblique wall.
Next, in step S15, the user clicks the "opening" tab on the command palette 43 to input opening information. An opening input screen is shown in FIG. The opening is entered by clicking on the start and end points, similar to a wall. In this case, the input can be made regardless of the type of door, sliding door, wooden fitting, aluminum sash, and the like.
Next, in step S16, the user clicks on the "bearing wall" tab of the command palette 43 and inputs bearing wall information. FIG. 8 shows the load-bearing wall input screen. Clicking the "Existing Strength Wall" tab on this screen displays the existing strength wall. Select the type (strike and face material) and magnification and enter it.
Next, in step S17, the "column" or "automatic" tab of the command palette 43 is clicked to input column information. FIG. 9 shows the pillar input screen. Column input is performed by clicking the column position. When "Auto" is selected, pillars are automatically placed at both ends of the wall, both ends of the opening, and the vertex of the room section, so that excess or shortage can be added or deleted to correct the actual situation .
Next, in step S18, the user clicks the "foundation reinforcement" tab on the command palette 43 to input foundation reinforcement information. FIG. 10 shows a basic reinforcement position input screen. The basic reinforcement position input is input by clicking the start point and the end point of the position where the basic reinforcement is performed.
Next, in step S19, the "balcony" tab of the command palette 43 is clicked to input balcony information. FIG. 11 shows a balcony input screen. Balcony input is performed by inputting the vertex so as to close the balcony section. In addition, the balcony here means what is structurally integrated with the building, and does not include a ready-made aluminum balcony or the like.
Next, in S20, the user clicks the “room name” tab of the command palette 43 to input room name information. FIG. 12 shows a room name input screen. To enter a room name, click and select a name to be entered from the displayed room name window, and click inside the relevant room to enter.
Next, in step S21, the user clicks the "found area editing" tab on the command palette 43 to confirm found area editing information. FIG. 13 shows the found area editing screen. The found area is automatically calculated by inputting S13 to S20. If the displayed area is different from the actual one, select the edit value and correct it.
[0011]
When the condition of the existing house is input as above, the earthquake resistance diagnosis is started. In step S22, the user clicks the "standard method" tab of the mode palette 42, and clicks the "standard method determination" tab of the command palette 43 to determine whether or not it conforms to the Building Standard Law. The reference method determination screen is shown in FIG. The determination result is displayed in the diagnostic information window 141, and the wall amount, the wall arrangement balance, the necessary wall amount, and the like are determined, and it is determined whether or not the wall conforms to the Building Standard Law.
Next, in step S23, the "standard method" tab on the mode palette 42 is clicked, and the "seismic determination" tab on the command palette 43 is clicked to determine the seismic performance. FIG. 15 shows the seismic performance determination screen. In FIG. 15, the "earthquake resistance determination" tab corresponds to the "home well determination" tab. Although the seismic performance can be set arbitrarily, it is usually set based on the seismic performance specified in the Building Standards Law, and it is determined how strong or weak the seismic performance is based on the standard. The determination result is displayed in the diagnostic information window 151, and the safety factor of the wall amount, the eccentricity factor of the wall arrangement balance, the suitability of the joint, the suitability of the foundation, the overall performance, and the like are determined.
Next, in S24, the “placement” tab of the mode palette 42 is clicked, and the “judgment” tab of the command palette 43 is clicked to determine the arrangement of the wall. FIG. 16 shows a wall arrangement determination screen. The determination result is displayed in the diagnostic information window 161, and it is determined how much the currently existing wall amount satisfies the required wall amount based on the Building Standards Law.
[0012]
Next, in S25, the condition of the joint between the column and the wall is determined. First, the "joint" tab of the mode palette 42 is clicked, the "through column attribute" tab of the command palette 43 is clicked, and the through pillar is displayed by clicking the through pillar among the displayed columns. Next, when the "joint" tab of the mode palette 42 is clicked and the "judgment" tab of the command palette 43 is clicked, a joint judgment table window 171 shown in FIG. 17 is displayed. The judgment result indicates the joining status such as the type and quantity of the column end joints for each joining device, and judges how much the joining condition is satisfied with respect to the Building Standard Law.
The results input and determined in S13 to S24 are stored in the database 10 in S25. In addition, an Excel file in which a plan view is incorporated is created as necessary, and the Excel file is stored in the database 10 together with CSV data of a wall, a column, a column end joint, and other members.
[0013]
The seismic resistance is diagnosed in each of the above steps, but the results entered and judged in each step are expert data, so customers can edit these data and diagnostic results in an easy-to-understand manner and send a seismic diagnosis report. Created. FIG. 18 shows an example of a seismic performance judgment table for explaining the result of the seismic diagnosis to the customer. In addition to the general condition of the diagnosed property, the judgment table includes the results of the determination of the amount of walls, the suitability of the balance (eccentricity) of the load-bearing walls, the status of the presence or absence of joints, the suitability of the basic shape, and comprehensive judgment. The degree of seismic resistance and the need for seismic retrofitting work are presented. This corresponds to S3 in FIG.
[0014]
When it is determined that the seismic reinforcement work is necessary and the customer requests an estimate of the seismic reinforcement work, the design of the seismic reinforcement work is started in S4. FIG. 19 shows a flow chart of design of seismic retrofitting work and creation of an automatic estimate. The design of the seismic retrofitting work is performed using the above-mentioned seismic retrofit diagnosis and construction design software.
First, when the earthquake-resistant diagnosis / construction design software is started in S31, the same earthquake-resistant reinforcement work design screen as the screen for the earthquake-resistant diagnosis is displayed. The displayed startup screen is that shown in FIG. Next, in S32, construction property data is input to the computer. The construction property data includes the property summary data, wall data, opening data, bearing wall data, column data, foundation reinforcement data, balcony data, and room name input data entered in S13 to S20 at the time of the earthquake resistance diagnosis in FIG. It is captured.
Next, in step S33, the user clicks on the "bearing wall" tab of the command palette 43 and inputs bearing wall information to be newly added for reinforcement. The load-bearing wall input screen is the same as that shown in FIG. On this screen, click the “Reinforcement additional shear wall” tab, select the type of wall material to be added (strike and face material) and magnification, and enter the shear wall in the same way as inputting the existing shear wall at the time of the earthquake resistance diagnosis I do. When you enter the location of the load-bearing wall, the found area is recalculated.
[0015]
Next, in step S34, the user clicks the "load-bearing wall automatic placement" tab on the command palette 43 to display a load-bearing wall automatic placement condition setting palette. FIG. 20 shows the load-bearing wall automatic arrangement input screen. Set the target grade and conditions on this screen.
The target grade is the magnitude of the reinforcing strength in the reinforcement work. Based on the Building Standard Law, the grade 1 regarding earthquake resistance is the amount of walls that satisfy the Building Standard Law, and in S22 in FIG. .25, an eccentricity of 0.3 or less, and the grade 2 for earthquake resistance is 1.25 times the wall amount of the Building Standards Law. In S22 of FIG. 0.3 or less, the grade 3 regarding earthquake resistance is 1.5 times the wall amount of the Building Standards Law, and in S22 of FIG. Therefore, the higher the grade, the higher the construction cost.
The conditions include a wall material to be newly added for reinforcement and its strength magnification, a target floor to be placed, and a placement target site (a distinction between an inner wall and an outer wall).
When a target grade and condition are input and an “automatic placement execution” button is clicked, a newly added wall material is automatically placed in the plan view. The logic of this automatic arrangement is set as follows.
(1) Add from the wall near the four corners.
(2) It is added to a blind wall and not to a wall with an opening such as a window.
(3) Considering the eccentricity, it is sequentially added to a symmetric position.
According to this logic, it is possible to design a seismic retrofitting work having a large seismic strength with a small amount of bearing wall and a small eccentricity. In order to execute the automatic placement based on this logic, there are means for determining whether or not the wall is close to the four corners, means for determining whether the wall is a blind wall or a wall having an opening, and an eccentricity ratio by adding a bearing wall. Means for determining the size of Then, first, one of the walls adjacent to the four corners is selected. At this time, if the selected wall is a wall having an opening, another wall adjacent to the four corners is selected. Then add a bearing wall to this wall. When the bearing wall is added, the wall filling rate is calculated and displayed. In order to further add a bearing wall, another wall adjacent to the four corners is selected. If the wall is a blind wall, a bearing wall is added to this wall. However, when there are a plurality of applicable walls to which a load-bearing wall can be added, the magnitude of the eccentricity is determined, and, for example, a wall on the diagonal side of the previously added wall is selected and the load-bearing wall is selected. Add. When the bearing wall is added, the wall filling rate is calculated and displayed. When a load-bearing wall is further added, it is determined whether the wall is close to the four corners or not, and the wall close to the four corners is preferentially selected. Add load-bearing walls until reaching.
When the automatic placement processing is completed, the determination window 44 on the plan view screen changes, and the eccentricity and the wall filling rate at that time are displayed. When the load-bearing wall is automatically arranged, the found area is recalculated.
Next, in step S35, the user clicks the "column" tab on the command palette 43 and inputs the position of the column to be added. The column input screen is the same as that in FIG. 9 at the time of the earthquake resistance diagnosis, and is input in the same manner as that at the time of the earthquake resistance diagnosis. When pillar input is performed, the found area is recalculated, and the eccentricity of the determination window 44 changes.
Next, in step S36, the user clicks the "foundation reinforcement" tab of the command palette 43 and inputs the position of the foundation reinforcement to be added. The foundation reinforcement input screen is the same as that in FIG. 10 at the time of the earthquake resistance diagnosis, and is input in the same manner as that at the time of the earthquake resistance diagnosis. In this case, the eccentricity of the determination window 44 changes for each input of the base position.
Next, in step S37, the user clicks the "found area editing" tab on the command palette 43 to check the found area editing information. The found area edit screen is the same as that in FIG. 13 at the time of the earthquake resistance diagnosis. The found area is automatically calculated by inputting S33 to S36. If the displayed area is different from the actual one, select the edit value and correct it.
[0016]
Based on the load-bearing walls, columns, and foundations added in S33 to S36, the building standard is determined in S38. The determination of the Building Standard Law in S38 is performed in the same manner as in S21 of FIG. Since the target grade should be satisfied by adding the load-bearing walls, columns, and foundations in S33 to S36, the judgment should be passed in the judgment of the Building Standards Law in S38. , The flow returns to any one of S33 to S36, and the additional check of the load-bearing walls, columns, and foundations is performed again until a pass is determined.
If a pass determination is made in S38, the process proceeds to S39, and seismic performance determination is performed. The determination of the seismic performance at S39 is performed in the same manner as at S22 in FIG. The seismic performance judgment in S39 should also be conformance judgment, but if it is not a conformity judgment, the flow returns to any of S33 to S36 according to the content and the additional check of the load-bearing walls, columns, and foundations is again performed until a pass judgment is obtained. Perform The presence / absence of the joint is input depending on the situation at the site. However, if there is at least one “absence”, it becomes incompatible. If all the items meet the predetermined grade in S39, the arrangement of the wall is determined in S40, and the joint is determined in S41. The determination of the wall arrangement in S40 and the determination of the joint in S41 are performed in the same manner as in S23 and S24 in FIG. Although conformity determination should be made in these steps as well, if it is not conformity determination, the flow returns to any of S33 to S36 in accordance with the contents to perform a recheck.
[0017]
The design of the seismic retrofitting work is completed by S30 to S41. These results are stored in the database 10 in S42. Further, in S43, a plan view and CSV data of the types and quantities of members required for the reinforcement work are created as Excel files and stored in the database 10.
[0018]
Next, in S44, a seismic retrofitting work estimate item for performing the seismic retrofitting work designed in S30 to S41 is created. That is, when an instruction to create an estimate of the seismic retrofitting construction work is instructed on the menu bar 46, the customer name, the type of member necessary for the reinforcement work, the quantity, the estimated unit price, the estimated amount, the cost unit price, and the like are obtained from the CSV data stored in the database 10. The cost amount, the estimated unit price of the repair and foundation-related costs, the estimated amount, the cost unit price, the cost amount, the found area, and the like are taken in. Further, the man-hour is automatically calculated, and the estimated amount including the gross profit is automatically calculated. In the man-hour calculation, the required man-hour is set as a fixed value for each member required for the reinforcement work, and the repair unit and the basic relation are included in the estimated unit price in advance.
[0019]
FIG. 21 shows an example of the seismic retrofitting construction estimation detail screen. The estimated unit price, cost unit price, and gross profit rate are set in the database 10 in advance as initial values, but can be manually corrected on the seismic retrofitting work estimate detail screen. When the seismic retrofitting work estimation details are finally determined, the contents are stored in the database, and the design of the seismic retrofitting work in S4 of FIG. 1 is completed.
[0020]
Next, a seismic estimate is prepared in S45 based on the seismic retrofitting work estimate details obtained in S44. In S45, the contents of the seismic retrofitting work estimation details in S44 are edited into a quote in a predetermined format to create a seismic retrofitting work estimate. FIG. 21 shows an example of the prepared seismic estimate. In addition, if necessary, as an attached estimate, the seismic performance judgment table in FIG. 22, the wall amount / wall arrangement diagnosis table in FIG. 23, the eccentricity calculation table in FIG. 24, the wall amount calculation plan view in FIG. A part determination table, a reinforcement work document such as a joint plan view in FIG. 27, a construction drawing, and the like are created. The created seismic retrofitting work estimate is stored in the database 10 in S46, and the automatic creation of the seismic retrofitting work estimate in S5 of FIG. 1 ends.
The estimate sheet for earthquake-resistant reinforcement work automatically created is proposed to the customer, and the customer determines whether or not to order the work in S6 of FIG. In this case, as described above, the higher the grade of the reinforcement work, the higher the construction cost will be. Therefore, if a seismic reinforcement work estimate is prepared for each grade, the customer must select the grade of the reinforcement work to order based on the cost. Can be. At this time, it is also possible to take into account that the contents of insurance regarding earthquakes described later change according to the grade. When the customer designates the grade and places an order for the construction, the seismic retrofitting work of the grade is performed in S7.
When the construction is completed, a certain period of warranty is provided for the construction in S7. Set by reflecting. In other words, in the case of the third class of the highest level of seismic retrofitting work, the insurance money related to the earthquake will cover the entire amount of rebuilding costs in case of complete collapse due to earthquake, repair costs in case of partial damage or repair costs in case of damage, and In the case of (3), it is set so as to compensate for the cost of 1/2 of the third class, and in the case of the third class, it is set so as to compensate for the cost of 1/3 of the third class.
[0021]
【The invention's effect】
As described above, according to the present invention, it is possible to design a highly reliable seismic diagnosis and a seismic retrofitting work that conforms to the Building Standards Law and other various laws and standards, and has no individual differences among diagnosticians and designers. .
In addition, since the contents of the seismic diagnosis and the reinforcement work are automatically created by the seismic diagnosis / construction design software, the results can be clearly presented to the customer.
In addition, estimates for seismic retrofitting work can be automatically created using seismic diagnosis / construction design software.
In addition, the customer can order and execute the proposed seismic retrofitting work and receive indemnified insurance for preferential earthquakes according to the contents of the work.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a system configuration of an earthquake-resistant diagnosis system and an earthquake-resistant reinforcement construction system according to the present invention.
FIG. 2 is a flowchart showing a function and an operation flow of an earthquake-resistant reinforcement assurance method using the earthquake-resistant reinforcement work design system according to the present invention.
FIG. 3 is a flowchart illustrating a procedure of a seismic diagnosis according to the present invention.
FIG. 4 is a front view showing an example of a start screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 5 is a front view showing an example of a property outline input screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 6 is a front view showing an example of a wall input screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 7 is a front view showing an example of an opening input screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 8 is a front view showing an example of a shear wall input screen of the earthquake resistance diagnosis / construction design software according to the present invention.
FIG. 9 is a front view showing an example of a column input screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 10 is a front view showing an example of a basic reinforcement position input screen of the earthquake resistance diagnosis / construction design software according to the present invention.
FIG. 11 is a front view showing an example of a balcony input screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 12 is a front view showing an example of a room name input screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 13 is a front view showing an example of a found area editing screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 14 is a front view showing an example of a standard method determination screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 15 is a front view showing an example of a screen for judging seismic performance of the seismic diagnosis / construction design software according to the present invention.
FIG. 16 is a front view showing an example of a screen for judging a wall arrangement of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 17 is a front view showing an example of a joint determination screen of the earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 18 is a conceptual diagram showing an example of a seismic performance judgment table determined by the seismic diagnosis method according to the present invention.
FIG. 19 is a flowchart for explaining the procedure of the earthquake-resistant construction design method according to the present invention.
FIG. 20 is a front view showing an example of a screen for automatically arranging load-bearing walls of earthquake-resistant diagnosis / construction design software according to the present invention.
FIG. 21 is a conceptual diagram showing an example of an estimate created by the method for creating an estimate of earthquake-resistant work according to the present invention.
FIG. 22 is a conceptual diagram showing an example of a seismic performance judgment table created by the seismic construction design method according to the present invention.
FIG. 23 is a conceptual diagram showing an example of a position diagnosis table for a wall quantity / wall created by the seismic design method according to the present invention.
FIG. 24 is a conceptual diagram showing an example of an eccentricity calculation table created by the earthquake-resistant construction design method according to the present invention.
FIG. 25 is a conceptual diagram showing an example of a wall amount calculation plan view created by the earthquake-resistant construction design method according to the present invention.
FIG. 26 is a conceptual diagram showing an example of a joint determination table created by the earthquake-resistant construction design method according to the present invention.
FIG. 27 is a conceptual diagram showing an example of a joint plan view created by the earthquake-resistant construction design method according to the present invention.
[Explanation of symbols]
10 Database
15 Network
20, 21, 22, 23 terminal device
24, 25, 26, 27 PC
28, 29, 30, 31 Seismic diagnosis and construction design software
40 Start screen
41 Plan Window
42 Mode Palette
43 Command Palette
44 Judgment window
45 Status panel
46 Toolbar and Menu Bar

Claims (9)

One or more computers and a database are connected to each other by a data bus or a network, and the computer is configured based on wall data, opening data, load-bearing wall data, and column data of the existing house, It is characterized by comprising seismic resistance diagnosis means for judging wall arrangement balance, column end joints, conformity of foundation shape and seismic performance, and construction design means for designing seismic reinforcement work for each of the data. Seismic reinforcement construction design system. The seismic retrofitting design system according to claim 1, further comprising: an estimate creating unit that creates an estimate of the seismic retrofitting work. The database stores customer data as the owner or resident of an existing house, property data of the existing house, diagnosis result data determined by the seismic diagnosis means, and design data designed by the construction design means. The seismic retrofitting design system according to claim 1, wherein: Diagnosing the seismic performance of the existing house; designing the seismic reinforcement work according to the grade of the seismic reinforcement work according to the diagnosis result; performing the seismic reinforcement work according to the design result; Extracting insurance information on earthquakes having different security contents according to the class after completion of the construction. Storing the property data of the existing house in the earthquake-resistant diagnosis / construction design software; storing the wall position of the existing house; storing the opening position of the existing house; A step of storing a type and a magnification, a step of storing a pillar position of the existing house, a step of storing a foundation reinforcement position of the existing house, and determining a wall amount and a wall arrangement balance based on the stored data. A step of determining the strength magnification for the seismic performance according to the Building Standards Act; a step of determining the degree of safety for the required amount of the placed wall quantity according to the Building Standards Act; A method for diagnosing earthquake resistance, comprising a step of determining a degree of safety for a required amount. Importing property data, wall position, opening position, load-bearing wall type and magnification, pillar position and foundation reinforcement position into the computer, and the type and magnification of the load-bearing wall newly added for reinforcement And automatically arranging the load-bearing walls in accordance with the grade of the desired reinforcement strength, storing the position of the column to be added for reinforcement, and storing the position of the foundation reinforcement to be added for reinforcement. Performing a step of determining a wall arrangement balance and a necessary wall amount based on the added load-bearing walls, columns, and foundations; and a step of determining a strength magnification for seismic performance according to the Building Standards Act. A step of determining the degree of safety of the wall quantity against the required amount according to the Building Standards Act; Seismic reinforcement work design method, which comprises a. Means for determining whether or not the wall is close to four corners, means for determining whether the wall is a blind wall or a wall having an opening, and means for determining the magnitude of the eccentricity due to the addition of the load-bearing wall The said load-bearing wall is added from a wall near four corners, is added to a blind wall, is not added to a wall having an opening, and is arranged so as to reduce the eccentricity. 6. The seismic retrofitting design method according to 6. In each of the step of storing the type and magnification of the load-bearing wall to be added, the step of automatically arranging the load-bearing wall, the step of storing the position of the column to be added, and the step of storing the position of the foundation reinforcement to be added, the filling of the additional member The seismic retrofitting design method according to claim 6, wherein the rate and the eccentricity are calculated and displayed. Loading the type, quantity, estimated unit price, cost unit price, and estimated unit price of repair and foundation-related costs and unit cost required for construction by the method for designing seismic retrofitting construction according to claim 6 into a computer; A method for creating an estimate of seismic retrofitting work, comprising: calculating a man-hour for the member by a computer; and calculating an estimated amount of the seismic retrofitting work based on the data and the man-hour by the computer.

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