JP4307611B2 - Office building design support equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an apparatus for supporting the design of an office building (office building architecture), and more particularly, a core (for example, a staircase, an elevator hall, an elevator, and a water supply) that is a fixed part disposed at substantially the same position through each floor. Etc.) can be performed in a relatively short time and with a quality of a certain level or more, even if it is not an expert in office design.
[0002]
[Prior art]
A conventional technique of this type is disclosed in Japanese Patent Laid-Open No. 7-296036 previously proposed by the present applicant.
In other words, in this conventional technology, conditions such as the entrance road conditions of the site, the presence / absence of the parking lot and its method, and the position of the entrance / exit of the building are input, and are constructed in advance according to the input conditions. It was supposed to search the database and select the core format. In other words, after investigating and examining existing or new buildings, this conventional technology concluded that it would be possible to standardize the design of cores in buildings. Invented as a result of finding out that they can be roughly classified based on the above three conditions.
[0003]
And according to this conventional technique, even if it was not an expert, the effect that the design of the core part in an office building can be performed in a comparatively short time and with high quality was acquired.
[0004]
[Problems to be solved by the invention]
Certainly, according to the conventional technique, a predetermined effect can be obtained by the above configuration, but further improvement has been desired.
That is, in the above conventional technique, a database is searched based on input conditions, an appropriate format is selected from a plurality of cores built therein, and is displayed on the screen, for example. I was trying to do it. For this reason, a core format other than the core format built in the database cannot be presented to the user. Therefore, in order to widen the range of selection by the user, the number of types of core formats to be constructed in the database has to be increased, and there is a drawback that the cost for constructing the database increases.
[0005]
The present invention has been made paying attention to such problems to be solved by the conventional technology, and increases the types of core formats that can be selected by the user without increasing the burden of database construction work. The purpose is to provide a design support device for office buildings.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the present invention is an apparatus for supporting the design of a core in an office building, and includes each of the structural units for each function such as a staircase, an elevator hall, an elevator, and a water circumference included in the core. , a database constructed as data that can replaced in its core, a condition input means for inputting a predetermined condition, and selecting means for searching a database according to the predetermined condition inputted to output to select the format of the core, the Position replacement means for replacing the positions of the respective constituent units of the selected cores, and selection display means for sequentially or collectively displaying a plurality of types of cores in which the positions of the respective constituent units are replaced by the position replacement means. , With .
[0007]
According to the present invention, for example, result of searching the database according to a predetermined condition, even in format one type of selected out cores, by replacing the selected output component unit in the core, as if the plurality of types The core format is selected, and the plurality of types of cores are displayed sequentially or collectively.
That is, the database, in response to a predetermined condition in advance to build one or several core form, interchanged structural units within the core for selected output is one or several core form was in response to a predetermined condition Since the types of displayed core formats will increase several times, the user may be provided with a selection range several times that of the core formats stored in the database. it can.
[0008]
There are various concrete measures to replace each structural unit in the core. For example, the dimensions such as stairs, elevator halls, elevators, water circumferences, etc., are set by this design support device. If the intervals are matched, the structural units can be easily replaced.
In addition, as the predetermined condition for searching for the core, for example, as disclosed in the above-mentioned publication, there are three conditions such as the road access condition of the site, the presence / absence of the parking lot and its method, and the position of the entrance of the building Well, if such conditions are used, it is possible to select an optimum core type corresponding to the actual road entrance conditions. Alternatively, the total floor area and the reference floor area may be used as the predetermined conditions, and even under such conditions, the core type suitable for the scale of the office to be built can be selected.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a system configuration according to an embodiment of the present invention. This embodiment is a medium to small scale (here, a total floor area of 3000 to 6000 m ² or less and a height of 31 m). In the following, a building having five or more floors is considered.) This is applied to an office building design support system.
[0010]
In other words, this system is configured around a computer 1 that includes an arithmetic processing unit, necessary memory, interface circuit, and the like.
The computer 1 includes a storage device 2 composed of, for example, a bird disk, an input device 3 composed of a keyboard and a mouse for inputting data by an operator's operation, and a display device composed of, for example, a CRT. 4 and a printing apparatus 5 configured by, for example, a laser printer capable of outputting detailed design drawings are connected via an interface (not shown).
[0011]
Here, for example, the “office design support program” is read into the memory of the computer 1 from the storage device 2 when the power is turned on, and the computer 1 performs processing according to the “office design support program”. It is supposed to run. As shown in FIG. 2, this “office design support program” is roughly divided into three types of processes: a plane design support process 10, a cross-section design support process 20, and an elevation design support process 30 in that order. It is a program to be executed, and is an interactive program in which processing proceeds when an operator appropriately inputs data according to a menu displayed on the display device 4.
[0012]
On the other hand, the storage device 2 stores data necessary for appropriately executing the processes 10 to 30 in addition to the program and the like.
In particular, a database necessary for the planar design support processing 10 described in detail later is stored. This database is a database necessary for supporting the design of the core part in the planar design. Specifically,
(1) Site access conditions (2) Presence / absence of parking lot and method (3) Location of building entrance / exit The optimal core type is classified.
[0013]
In addition, one solution does not necessarily exist for one combination of each item of (1) to (3), and there may be no solution depending on the combination, and conversely, there are a plurality of solutions. However, since the basic idea is the same regardless of whether there is one or more solutions, the following explanation is based on the assumption that there is only one solution. The database is constructed in advance by classifying the cores of existing office buildings and newly constructed office buildings according to the items (1) to (3).
[0014]
Then, the planar design support processing 10 causes the operator to input the above conditions (1) to (3), searches the database stored in the storage device 2 according to the combination of the input conditions, and searches for the optimal solution for the core. Is to be selected. The optimal solution for the selected core is referred to as a standard core (A type).
Furthermore, as the core unit, in this embodiment, a staircase CS, an elevator hall CH, an elevator CE, and a water supply (a boy's toilet, a women's toilet, a hot water chamber, etc.) CW are considered, and these units can be exchanged. It is said. Specifically, by aligning the standard module of each structural unit of the core stored in the database with the span (column dimension), the position of each structural unit can be changed without depending on the span. I have to. Here, “match” means, for example, that when the basic span is 5500 mm, the standard module of each constituent unit of the core is set to 2750 mm (= 5500 mm / 2), so that two constituent units are included in one span. Or 1.5 units within 3 spans.
[0015]
When a standard core (A type) is selected, the A type is displayed on the display device 4, and the operator is made aware of how many types can be selected by replacing each structural unit. It has become. For example, if a total of 6 types can be displayed by switching the structural unit, when displaying the A type, the display is “1/6” and the currently displayed type is 6 types. The operator can recognize that it is the first type, and in accordance with the operation of the operator, each type is sequentially displayed such as B type “2/6”, C type “3/6”. It is like that.
[0016]
Furthermore, one of the displayed types is selected as the final optimum solution of the core by the operator.
And based on the shape of the standard floor (usually more than 2 floors) and the special floor (usually the 1st floor where people and cars go in and out) including the optimal solution of the core so selected, it matches the actual site Determine the floor plan for the standard floor and special floor.
[0017]
In other words, the plan shape including the optimum solution of the selected core is applied to the actual site along with the span of the pillars, but the size of the core is constant even if the floor area of each floor is slightly different. The vertical and horizontal dimensions of the office part may be enlarged or reduced so as to match the actual size of the site without changing the core part and the span of the planar shape including the optimal solution of the core.
[0018]
In addition, in this embodiment, a fixed basic span (for example, 5500 mm) is set, and the pillars at both ends and one of them are set. The span between the inner pillars (spans at both ends) is variable (5500-6500 mm) within a predetermined range, and the dimension between the pillars and the outer wall is variable (850-2500 mm), and these variable values It is made to adapt to the actual site by appropriately changing.
[0019]
When the planar design support process 10 is completed, a cross-section design support process 20 is executed. In the cross-section design support process 20, conditions necessary for the cross-section design such as the number of floors and the ceiling height of the building are input. Then, the cross-sectional shape of the building is determined according to the input conditions. The elevation design support processing 30 displays the contents of the elevation database (elevation pattern) stored in the storage device 2 on the display device 4 when the operator desires design support. Then, a desired elevation pattern (for example, a pattern in which each window is independent, a pattern in which each window is connected, etc.) is selected from the displayed elevation patterns.
[0020]
When the planar design support processing 10, the cross-section design support processing 20, and the elevation design support processing 30 are completed, the overall design of the office building is performed based on the plane design, the cross-section design, and the elevation design determined in each processing. The process 40 is completed, the design drawing is stored in the storage device 2, and the design drawing 40 is printed by the printing device 5.
[0021]
FIG. 3 is a flowchart showing a more detailed process flow of the planar design support process 10. Hereinafter, the operation of the planar design support process 10 will be described with reference to FIG.
That is, when the planar design support process 10 is started, first, in step 101, the operator is made to input the actual road entrance condition. Specifically, for example, the display device 4 displays a pattern obtained by patterning the relationship between the site S and the road R as shown in FIGS. 4 (1) to 4 (5), and the same contact with the actual site is displayed. Let the operator choose what is in the road conditions. 4 (1) shows a pattern in which only one short side of the rectangular site S is in contact with the road R, and FIG. 4 (2) shows a pattern in which only one long side of the site S is in contact with the road R. (3) is a pattern in which both short sides of the site S are in contact with the road R, (4) is a pattern in which one short side and one long side is in contact with the road R, and (5) is both This is a pattern in which the short side and one long side are in contact with the road R. It is naturally possible to prepare other arbitrary patterns. The result selected by the operator is stored in a predetermined storage area in the computer 1 as a tangential condition.
[0022]
Next, the process proceeds to step 102 where the operator inputs whether or not a parking lot is to be built inside the building, that is, whether or not there is a parking lot. If it is input here that a parking lot is unnecessary, the next step 103 is not executed, and the routine proceeds directly to step 104. However, when it is input in step 102 that a step parking lot is necessary, the process proceeds to step 103 and the operator inputs the parking method of the parking lot. For example, a plurality of parking lot systems (three-dimensional parking lot, underground parking lot, multistage parking lot, etc.) are displayed on the display device 4, and an operator is selected from these. The result selected by the operator is stored in a predetermined storage area in the computer 1 as a parking lot condition.
[0023]
The process proceeds from step 102 or step 103 to step 104, and the operator inputs the position of the entrance of the building. Specifically, for example, the patterns of positions of human entrances (indicated by Δ) and vehicle entrances (indicated by Δ) with respect to buildings as shown in FIGS. 5 (1) to (5) are displayed. Among them, the operator selects the optimum entrance / exit position in consideration of the actual road conditions around the site (front direction, road traffic conditions, etc.). Incidentally, FIG. 5 (1) shows a pattern in which a human doorway and a vehicle doorway are on one short side of a building having a rectangular plan shape, and FIG. 5 (2) is a human doorway on one short side of the building. (3) is a pattern where there is a human doorway on one short side of the building and a vehicle doorway on the other short side, (4) Is a pattern with a human doorway and a vehicle doorway on one long side of the building, and (5) has a human doorway on one long side of the building and a vehicle doorway on one short side It is a pattern. In addition, it is naturally possible to prepare an arbitrary pattern, and a pattern when a parking lot is unnecessary may be prepared separately. The result selected by the operator is stored in a storage area in the predetermined computer 1 as an entrance / exit condition.
[0024]
Next, the process proceeds to step 105, the database stored in the storage device 2 is searched according to the roadway conditions, parking conditions and entrance / exit conditions stored in the predetermined storage areas, respectively, and the first floor and the reference Select the floor core type and use it as the standard core (A type).
Then, the process proceeds to step 106, and the type A core selected in step 105 is displayed on the display device 4 and can be displayed by replacing the structural unit of the core, for example, “1/6”. And the current core number are also displayed.
[0025]
Next, the process proceeds to step 107, and it is confirmed with the operator whether or not the currently displayed core is adopted. Here, the operator selects “YES” if satisfied with the displayed core, and selects “NO” if not satisfied or wants to see other types. If the operator's selection in the step 107 is “NO”, the process proceeds to a step 108 where the B type obtained by replacing the position of the A type structural unit is displayed and “2/6” is displayed. .
[0026]
Then, the process returns to step 107, and the operator is again confirmed. If “NO”, the process proceeds to step 108 again to display the C type.
That is, in step 105, when an A type core as shown in FIG. 6 is selected, it is displayed on the display device 4 in step 106. If this type of core is selected, for example, FIG. As shown in (5), if five variations of types B to F are considered, if these types are sequentially displayed by the processing in steps 106 to 108, the operator can see six types A to F. One can be selected from the types. In the A type shown in FIG. 6, the staircase CS, the elevator hall CH, the elevator CE, and the water flow CW are arranged in this order from the left side in the drawing, and an outdoor staircase is provided outside the building. And in the B type shown in FIG. 7 (1), it arranges in order of CS-CE-CH-CW from the left side, and in the C type shown in FIG. 7 (2), it goes in order of CS-CW-CH-CE from the left side. The D type shown in FIG. 7 (3) is arranged in the order CS-CW-CE-CH from the left side, and the E type shown in FIG. 7 (4) is arranged in the order CH-CE-CS-CW from the left side. In the F type shown in FIG. 7 (5), CE-CH-CS-CW are arranged in this order from the left side.
[0027]
If the operator selects “YES” in step 107, the process proceeds to step 109, where the core type displayed on the display device 4 is determined as the final optimum solution of the core. At that time, the planar shapes of the first floor and the reference floor including the core determined as the optimal solution are displayed on the display device 4 to allow the operator to confirm.
[0028]
Next, the process proceeds to step 110, and processing for matching with the actual site is executed. Specifically, as shown in FIG. 8, the vertical and horizontal dimensions of the designed planar shape F represented by the solid line are enlarged (or reduced) so as to match the shape of the actual site S represented by the chain line. That's fine. However, the size of the core C is left as it is.
Note that when executing this step 110, column splitting is actually a problem, but in this embodiment, the basic span is set as described above, the spans at both ends, the outer wall, and the columns. By making the dimensions between them variable and appropriately changing these variable values, it is possible to cope with the case where the actual shape of the site S cannot be matched only by increasing or decreasing the basic span. For example, in the example shown in FIG. 9, the interval between the four pillars in the center (part (1)) is a fixed basic span of 5500 mm, and the spans on both ends outside (2) are outside. It is variable between 5500-6500 mm, and the dimension (part (3)) between the outer wall and the column is variable between 850-2500 mm. The depth span (4) is variable below 14000. And the response to the actual site is to respond by increasing or decreasing the number of parts that become the basic span, increasing or decreasing the span at both ends, increasing or decreasing the dimension between the outer wall and the pillar, and increasing or decreasing the depth span. Yes.
[0029]
Then, the process proceeds to step 111, where the planar design completed by the process of step 110 is stored in a predetermined storage area of the storage device 2, and the current planar design support process 10 is terminated. Thereafter, as described above, the cross-section design support process 20 and the elevation design support process 30 are sequentially executed.
As described above, in the present embodiment, when designing the core in the office building, the conditions of the above (1) to (3) are input, the database is searched according to those conditions, and the core portion Therefore, even if it is not an expert, core design can be performed within a very short time. Moreover, since the quality of the database directly becomes the design quality, if a database is built based on an existing office design or a new office design as in the above embodiment, nobody can create a high-quality core design. But it can be done.
[0030]
In this embodiment, not only the standard core (A type) selected in step 105 is shown to the operator, but also other types of cores obtained by exchanging each structural unit in the standard core are also displayed. In this way, the operator can select the optimum solution from among these multiple types, so the range of user choices for the core is widened, and various designs can be made accordingly, improving the design quality. There is an advantage that helps.
[0031]
In addition, by replacing each constituent unit of the standard core, multiple types of cores are made candidates for the optimal solution, so there is no need to store the core format in the database for the number of optimal solutions. There is an advantage that the cost required for the construction of the storage device 2 can be reduced, and the memory capacity of the storage device 2 for storing the database can be reduced.
[0032]
Here, in the present embodiment, the condition input means is configured by the input device 3 and the processes of steps 101 to 104, the selection means is configured by the process of step 105, and the position is determined by the process of replacing the core structural units in step 106. Replacement means is configured, and selection display means is configured by the processing of steps 10 6 to 108.
In the above embodiment, the case where the present invention is applied to a design support system for small and medium-sized office buildings has been described. However, the application target of the present invention is not limited to this, for example, large-scale office work. It may be a design support system for office buildings. In that case, an existing office design that falls into a large-scale category is analyzed, and the database is constructed by classifying the core format according to the above conditions (1) to (3).
[0033]
In the above embodiment, the “office design support program” is an interactive program, and the operator selectively inputs data according to the display on the display device 4. However, the present invention is not limited to this. Alternatively, for example, a condition pattern as shown in FIG. 4 or FIG. 5 is separately displayed on the menu sheet, and the operator inputs the symbolized information according to the display of the menu sheet to the computer 1 by the input device 3. Good.
[0034]
In the embodiment described above, the cross-section design support processing 20 and the elevation design support processing 30 are also executed in addition to the flat design support processing 10, but the feature of the present embodiment is the flat design. Since it is a point related to the design of the core part in the support processing 10, only the plane design support processing 10 may be executed, and the cross-section design support processing 20 and the elevation design support processing 30 may be performed in the same manner as in the past.
[0035]
Furthermore, in the said embodiment, although three conditions of said (1)-(3) are applied as conditions for selecting a core, it is not limited to this, The total floor area of an office building and The standard floor area may be input, and the standard core format may be selected based only on the information. For example, if the conditions that the total floor area is 3000 to 6000 m ² and the standard floor area is 200 m ² are entered, two elevators from the transport capacity and two stairs from the Building Standard Law (to maximize the floor area) In addition, it is only necessary to search the database for a core suitable for the two floor booths for men and women based on the standard floor room area, and use the selected core as the standard core.
[0036]
In the above embodiment, a plurality of types of cores are sequentially displayed. However, the present invention is not limited to this, and a plurality of types of cores may be displayed in a lump. (For example, when the total number is 6, two may be displayed three by three).
[0037]
【The invention's effect】
As described above, according to the present invention, the data related to the core constructed in the database can be replaced within each core of the structural units included in the core, and the position of each structural unit is determined. Since the format of multiple types of cores to be replaced is displayed sequentially or collectively, it can be used for cores without incurring the problem of increasing the database construction cost or significantly increasing the memory usage for the database. There is an effect that the range of choice of the person is widened, and various designs can be performed accordingly, which helps to improve the quality of the design.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a system configuration according to an embodiment of the present invention.
FIG. 2 is a flowchart showing an overall outline of processing executed in the embodiment;
FIG. 3 is a flowchart showing a procedure of planar design support processing.
FIG. 4 is a diagram illustrating an example of a roadway condition.
FIG. 5 is a diagram illustrating an example of entrance / exit conditions;
FIG. 6 is a diagram illustrating an example of a selected standard core.
FIG. 7 is a diagram showing an example of another type of core obtained by replacing standard core constituent units.
FIG. 8 is a diagram illustrating a process for matching a search result with an actual site.
FIG. 9 is a diagram for explaining a relationship between a process for matching with an actual site and pillar division.
[Explanation of symbols]
1 Computer 2 Storage Device 3 Input Device 4 Display Device 5 Printing Device C Core CS Staircase (Unit)
CH elevator hall (unit)
CE elevator (component unit)
CW water circumference (unit)

Claims (1)

A device that supports core design in office buildings,
A database constructed as data that can be replaced within the core for each functional unit such as stairs, elevator halls, elevators, and water features included in the core,
A condition input means for inputting a predetermined condition;
And selecting means for decene the form of the core by searching the database according to the inputted predetermined condition,
Position changing means for changing the position of each constituent unit of the selected core;
Selection display means for sequentially displaying or collectively displaying a plurality of types of cores obtained by replacing the positions of the respective structural units by the position replacement means ;
Design support apparatus of the office building, characterized in that with.

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