KR102396259B1 - Providing method for building integrated system - Google Patents

Abstract

The present invention relates to a method for establishing a building integrated system having enhanced selectability, which comprises the following steps of: planning establishment of a building integrated system; and establishing the planned building integrated system, wherein the step of establishing the building integrated system includes: a basic information input step of receiving a drawing and a specification of a target building and a plurality of selective specifications about at least some configurations of the target building; a standardization step of determining a construction outline in a predetermined data format, a finishing material table, basic data for calculating construction costs, construction description, and construction methods from the drawing and the specification; a structure review step of referring to the standardized data and the drawing to divide the target building by sector; and dividing the drawing by individual sector unit of the target building and extracting only surface information on the structure from the drawing divided by sector to prepare an outside view for each sector to establish a structure 3D drawing database where the whole 3D drawing of the structure among the drawings divided for each sector is stored.

Description

Providing method for building integrated system

The present invention relates to a method for providing a building integration system.

Until now, it is common for designers or builders to manually calculate the architectural totals or to calculate them using individually provided programs. In addition, it is essential to pre-estimate the cost of materials, building materials, and labor costs for building construction based on the output quantity. In the planning stage of construction, such architectural integration and estimation is a comprehensive technology, such as cost planning, control of construction cost, and pursuit of economic feasibility of building completion, the need for integration is urgently needed.

Korean Patent Publication No. 10-2016-0025106

The present invention provides a method of constructing a building integration system capable of analyzing the structure of a target building based on drawings and specifications, performing integration by sector through this, and determining whether drawings are omitted.

In addition, it is to provide a plurality of integration reports according to optional finishing materials and construction types, and to provide a building integration system construction method that can refer to a schematic bird's eye view for each selection.

Another object of the present invention is to provide a method for providing an architectural integration system provided with a server management means to guarantee the operation of a network-related configuration, which is one of the key elements in the construction and operation of the architectural integration system, under various conditions.

Another object of the present invention is to provide a method for providing an architectural integration system that can easily secure the storage and storage of network-related configurations in various forms in the construction and operation of the architectural integration system.

In addition, in the construction and operation of the building integration system, various types of network-related configuration conditions are considered in various ways and operated to be selectively exposed to the outside, and a method of providing an architectural integration system that can be protected from external pollution sources and impacts. will provide

In addition, in the construction and operation of the building integration system, a method for providing an architectural integration system having a management unit having a structural feature to more stably implement the mounting state of the network-related configuration in various forms to protect it from vibration and vibration damage, etc. will do

The present invention provides a method for providing a building integration system, comprising: a basic information input step of receiving a drawing and a specification for a target building, and receiving a plurality of optional specifications for at least a part of the target building; a standardization step of determining a construction outline in a preset data format, a finishing material table, basic data of construction cost calculation, a construction statement and a construction method from the drawings and specifications; and a structural review step of classifying the target building by sector with reference to the standardized data and the drawings; The drawing is divided into individual units of the target building sector, only the surface information of the structure is extracted from the drawings divided by the sector to create an external view for each sector, and the entire 3D drawing of the structure among the drawings divided by the sector is stored and constructing a structure 3D drawing database, wherein the building integration system is performed by an integration server linked to the integration DB and the estimate DB, and the architectural integration system further includes a centralized management unit for managing the integration server. and the integration server includes one side server 123', the other side server 124', the 1-1 server 133', the 1-2 server 134', the 2-1 server 143', It includes a 2-2 server 144', a 3-1 server 153', and a 3-2 server 154'.

According to the present invention as described above, there are one or more of the following effects.

The present invention analyzes the structure of a target building based on drawings and specifications, and through this, it is possible to perform sector-by-sector integration and determine whether drawings are omitted. In addition, the present invention provides a plurality of integration reports according to optional finishing materials and construction types, and a schematic bird's eye view for each selection can be referred to. may reduce discomfort.

In addition, it is also possible to provide a plurality of integration reports according to optional finishing materials and construction types, and to provide a building integration system construction method that can refer to a schematic bird's eye view for each selection.

In addition, it is possible to provide a method for providing an architectural integration system provided with a server management means for securing the operation of a network-related configuration, which is one of the key elements in the construction and operation of the architectural integration system, under various conditions.

In addition, it is possible to provide a method for providing an architectural integration system that can easily secure the storage and storage of network-related components in various forms in the construction and operation of the architectural integration system.

In addition, in the construction and operation of the building integration system, various types of network-related configuration conditions are considered in various ways and operated to be selectively exposed to the outside, and a method of providing an architectural integration system that can be protected from external pollution sources and impacts. can provide

In addition, in the construction and operation of the building integration system, a method for providing an architectural integration system having a management unit having a structural feature to more stably implement the mounting state of the network-related configuration in various forms to protect it from vibration and vibration damage, etc. can do.

1A is a diagram illustrating an example of 3D modeling by a system for providing architectural totals according to an embodiment of the present invention.
1B is a block diagram showing the appearance of a system for providing architectural totals according to an embodiment of the present invention.
Fig. 2 is a block diagram showing the configuration of a bird's-eye view creation unit.
3 is a flow chart showing the appearance of a method for providing architectural totals according to an embodiment of the present invention. 4 is a flowchart illustrating a method for providing architectural totals according to another embodiment.
5 to 10 are schematic diagrams showing the main components according to FIG. 1B.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. Unless there is a specific definition or reference, the terms indicating the direction used in this description are based on the state indicated in the drawings. In addition, the same reference numerals refer to the same members throughout each embodiment. On the other hand, each component shown in the drawings may have an exaggerated thickness or dimension for convenience of description, and does not mean that it should actually be configured in a ratio between the corresponding dimensions or components.

A system including a building integration server according to an embodiment of the present invention will be described with reference to FIGS. 1B and 2 . 1B is a block diagram showing the appearance of a system for providing architectural totals according to an embodiment of the present invention, and FIG. 2 is a block diagram showing the configuration of a bird's-eye view preparation unit.

Integration has a strong meaning in the technical activity that calculates the quantity of materials and products required for construction, such as quantity, details, and first-class price, that is, construction quantity, and estimate has a strong meaning in terms of cost based on the implementation of such a building.

In this regard, the database in this embodiment is divided into the integration database 200 and the estimate database 300, but this is a division for convenience of explanation, and items stored in each database must be stored in each database. This does not mean that it is possible to store all search items by implementing it as a single database. Items stored in the integration database 200 and the estimate database 300 are as follows.

Classification information on construction methods that require integration such as reinforced concrete, masonry, plastering, etc., classification information on the type or form of construction such as foundation, column, beam, slab, floor, wall, staircase, retaining wall, etc. in reinforced concrete construction, foundation or Classification information on specific construction types of columns, stairs, beams, slabs, floors, walls, and retaining walls, standard specification information for calculating integration results based on user input information, textile graphic information according to finishing materials, construction type information the foundation structure according to

Traffic data and the like are stored. In addition, the integration database 200 and the estimate database 300 include the name of the structure in the drawings provided from the client, the soil

Construction methods for each structure such as barrier, excavation, backfill, residual soil treatment, ground clearance, and plastering concrete pouring, materials for each structure, equipment for construction of the structure, personnel costs, etc. may be stored.

The input unit 110 is a component that receives drawings, specifications, and the like of the integration client under the management of the integration server 100 . In addition, approval for the final totalization report is inputted from the final approver. The drawing conversion unit 120 converts the drawing input through the input unit 110 according to a predetermined format to be used inside the integration server 100 . Basic information standardization unit 130 from the drawings and specifications for the target building to the construction overview, finishing materials table, basic data of construction cost calculation, construction details and construction method in a preset data format, etc. In the analysis of the building construction It is a component that identifies necessary data, converts it into a certain format, and stores it. Drawings and specifications are stored in the integration database 200 , and standardized data may also be stored in the integration database 200 or a separate database. At this time, it is possible to separately store the drawing information in the structure 3D drawing database, it is also possible to store it redundantly, and it is also possible to store the drawing information in the 3D drawing database through a conversion process for 3D image output.

The structure review unit 140 classifies the target building by sector with reference to standardized data and drawings. As described above, the target building is classified by sector based on a certain standard by using information such as the structure name, construction form, and finishing material of the integration basic information stored in the integration database 200 . In this case, the type of structure according to the construction type based on the specification is given priority, and the sector can be divided by reflecting the type of building material. Meanwhile, in the drawings and the corresponding specifications, information on drawings connected to the drawings is described, and this information is used for connection and classification of structures for classification of sectors, as well as determining whether a specific drawing is omitted. can be used to When the omission of the drawings is confirmed, the omission of the drawings of the integration server may be notified to the manager through a separate notification means.

The bird's eye view creation unit 150 divides the input drawings into individual units of sectors of the target building, and then extracts only the surface information of the structures from among the drawings divided by sectors to create an external view for each sector. In addition, it is possible to add a contrast state according to the amount of light or to apply a textile graphic image stored in a database in advance in response to a finishing material. Specifically, the bird's eye view creation unit 150 includes a filter creation unit 151, a textile adjustment unit 153, and a bird's eye view creation unit 155, as shown in FIG. The filter creation unit 151 creates a filter indicating a contrast state for an external view for each sector according to a viewpoint and a light source at a specific location based on an input drawing, particularly a 3D drawing. The textile application unit 153 inquires for a finishing material corresponding to the external shape from the basic data standardized on the external shape for each sector at the point of time of a specific location. After that, the textile corresponding to the inquired finishing material is searched from the database and applied to the outline drawing.

The bird's eye view creation unit 155 creates a bird's eye view for each sector by synthesizing the created filter with the outer view to which the textile is applied. In the case of the external view for each sector, it is desirable to exclude all spatial information and volume information about a 3D object and consider only the surface information, or to make it 2D viewed from a specific point of view. In this case, compared to a general rendering process in which texturing is performed on a three-dimensional shape and then rendering is performed in consideration of the amount of observation, the quality may be slightly lowered, but the calculation speed is superior. Therefore, it is advantageous for the purpose of preparing a simple bird's eye view and using it as a reference material.

The integration module 170 may correspond to integration software or the like, and performs the integration process by utilizing data stored in the integration database 200 or the estimate database 300 .

Likewise, the estimate module 180 is a component that creates an estimate by using data stored in the integration database 200 and the estimate database 300 through general quotation software. However, it may be replaced as an input means for receiving an estimate prepared in-house or through service.

The 3D drawing inquiry module 190 requests and receives the 3D drawing data stored in the address when the user calls the network address of the structure 3D drawing data included in the integration report. At this time, the 3D drawing inquiry module 190 may convert the drawing stored in the structure 3D drawing database 400 into a format that can be displayed as a 3D image.

A method for providing architectural totals according to an embodiment of the present invention will be described with reference to FIGS. 3 and 4 . 3 is a flowchart illustrating a method for providing architectural integration according to an embodiment of the present invention, and FIG. 4 is a flowchart illustrating a method for providing architectural integration according to another embodiment. The integration provision method performed by the integration server linked with the integration DB and the estimate DB is performed through the following process. First, in the basic information input step (S100), drawings and specifications for the target building are input. At this time, a plurality of optional specifications for at least some components of the target building may be input. Specifically, a case in which there are a plurality of construction forms in a specific sector or overlapping finishing materials for a specific construction form may be input from a plurality of selective specifications. On the other hand, in the case where drawings, etc. are not provided for reasons such as not being prepared in the building construction planning stage, it can be replaced by selecting standard architectural modeling data according to the type and size of the building. Through this, even when the design stage is not progressed, it is possible to perform a rough integration and estimate through the information provided as much as possible.

Next, in the standardization step (S200), the input drawing is converted into a standard format for use in the integration server, and the construction outline, the finishing material table, the basic data of the construction cost calculation in a data format determined in advance from the input drawings and specifications, Decide on the construction details and construction method.

Next, in the structural review step (S300), the target building is classified by sector with reference to standardized data and drawings. In this case, the type of structure according to the construction type based on the specification and the state of drawing stored drawings are considered first, and the sector can be classified by reflecting the type of building material. For example, even if it is created as a separate drawing, one type of structure is shown across a plurality of drawings, and the type and ratio of building materials are more than a certain level

If they match, it can be treated as one sector. On the other hand, even when shown in a single drawing, a plurality of construction forms are included, and when the types and ratios of building materials input to the construction forms differ by more than a certain percentage, each construction form is classified as a separate sector. can be dealt with

In the step (S400) of creating an outline view/aerial view for each sector and building a structure 3D drawing database (S400), only the surface information of the structure from the drawings divided by sector is extracted to create an outline view for each sector. The sector-by-sector external view/aerial view creation step may include a filter creation stage, a textile application stage, and a sector-specific bird's eye view preparation stage.

In the filter creation step, a filter indicating the contrast state for the external shape for each sector according to the viewpoint and light source of a specific location is created, and in the textile application step, the external shape corresponds to the external shape from the data standardized on the external shape at the viewpoint of a specific location Inquires the finishing materials to be used, and applies the textile corresponding to the inquired finishing materials to apply the texture to the exterior. At this time, rather than performing a separate rendering, a 2D graphic image is converted into a 2D graphic image at a specific point in time and compositing is performed. After that, in the sector-by-sector bird's-eye view creation step, a bird's-eye view for each sector is created by synthesizing a filter indicating the contrast state according to the amount of light in the textile-applied external view. On the other hand, as described above, when a plurality of optional specifications for at least some of the target buildings are input, a separate external view or a bird's eye view may be prepared for each case. In other words, in the case of receiving a request for integration and estimate for a plurality of construction forms or finishing materials, it can be prepared for each case.

In addition, it is possible to build a structure 3D drawing database together with the outline drawing. However, the step of constructing the structure 3D drawing database can be flexibly performed in parallel between other steps, and in particular, when saving drawings in the standardization step, it is also possible to save the data while converting it into a form that is easy for 3D drawing output. . Thereafter, in the integration step ( S500 ), the target building is integrated for each sector. That is, the quantity of reinforcing bars, ready-mixed concrete, and formwork is calculated for each sector. At this time, an intermediate report is prepared in the form of an electronic totalization report. This includes a plurality of optional (overlapping) totalization reports according to a plurality of construction types or finishing materials, and an external view/aerial view of the prepared optional totalization report may be included. If there is a request for quotation, the quotation step (S600) is performed as shown in FIG. Estimation can be performed by inputting a report by software performance and service, as described above. Included in the completed estimate, the electronic totalization report. On the other hand, for selective or overlapping integration and quotation contents, a means selected by the client, for example, a selection button, etc. may be included, and a means for finally transmitting the selection back to the integration server, for example, sending an email It may include a button and the like.

The electronic totalization report shows the required amount of concrete, reinforcing bars, formwork, etc. required for the construction input by the user, and the result is the net amount and the prescribed amount, that is, 3%, 4%, 5%, 6%, 7% It can be expressed in divided amounts. In addition, information on basic conditions and materials required for construction, input by the client or written in specifications, etc., unit price, and total amount are displayed in the electronic total report. In addition, the outline view for each sector included in the electronic integration report can be provided as a single or a bird's-eye view of a plurality of sectors. can After that, the final integration/estimation report can be prepared by receiving the approval of the person in charge of the final selected electronic report based on the returned integration report.

Meanwhile, when a network address connected to the 3D data corresponding to the integration item in the 3D drawing database is called on the user terminal by the user, a 3D drawing including 3D data corresponding to the called integration item is displayed on the user terminal It may further include the step of It allows structural/visual characteristics of a plurality of options to be identified through an actual 3D image, rather than simply including only the external view in the integration report. Due to these structural characteristics, it is possible to grasp the structural and visual characteristics of the integration report through a method suitable for the purpose by providing two methods for identifying characteristics that can be distinguished by speed and specificity. Although the preferred embodiment of the present invention has been described above, the technical spirit of the present invention is not limited to the above-described preferred embodiment, and can be implemented in various ways without departing from the technical spirit of the present invention embodied in the claims. there is.

In addition, referring to FIGS. 5 to 10 , there is provided a method for constructing an architectural integration system with improved ease of selection, comprising: planning to construct an architectural integration system; Including the step of constructing the planned building integration system, wherein the step of constructing the building integration system includes receiving a drawing and a specification for a target building, and inputting a plurality of optional specifications for at least some components of the target building receiving basic information input step; a standardization step of determining a construction outline in a preset data format, a finishing material table, basic data of construction cost calculation, a construction statement and a construction method from the drawings and specifications; and a structural review step of classifying the target building by sector with reference to the standardized data and the drawings; The drawing is divided into individual units of the target building sector, only the surface information of the structure is extracted from the drawings divided by the sector to create an external view for each sector, and the entire 3D drawing of the structure among the drawings divided by the sector is stored and building a structure 3D drawing database.

Here, the building integration system is performed by the integration server interlocked with the integration DB and the estimate DB. The building integration system further includes a centralized management unit for managing the integration server, wherein the integration server includes a server on one side 123', a server on the other side 124', a 1-1 server 133', and a 1- It includes a second server 134', a 2-1 server 143', a 2-2 server 144', a 3-1 server 153', and a 3-2 server 154'.

The centralized management unit includes a central body 110 ′, a support connector 121 ′ installed under the central body 110 ′, and the central body via the support connector 121 ′. The support panel 122' which is installed on the lower part of 110' and supports the central body 110' and the support connector 121' is installed to be positioned on one side of the support connector 121'. ) and a plurality of one-side servers 123' cooled through It includes a lower monitoring part 120' including a plurality of other side servers 124' cooled through.

In addition, the left connector 131' installed to the left of the central body 110' and the left connector 131' are installed to be positioned on the upper surface of the left connector 131' and are installed on the left connector by the left connector. A plurality of 1-1 servers 133' to be cooled, located on the lower surface of the left connector 131', and installed to be reversed from the 1-1 server 133', are installed on the left connector body. A plurality of 1-2 servers 134' cooled by the left connector, and a first fluid 132' installed on the left side of the central body 110' via the left connector 131' The first monitoring parts 130' comprising A plurality of 2-1 servers 143', which are cooled by the right connector 141' on the right connector 141', and the lower surface of the right connector 141', A plurality of 2-2 servers 144' installed so as to be reversed from the 2-1 server 143' and cooled by the right connector 141' on the right connector, and the right connector 141' and a second monitoring part 140' including a second fluid 142' installed on the right side of the central body 110' via the .

In addition, the upper connector 151' installed above the central body 110' and the upper connector 151' installed to be positioned on one side of the upper connector 151' are cooled through the upper connector 151'. A plurality of 3-1 servers 153', which are located on the other side of the upper connector 151', are installed so as to be reversed from the 3-1 server 153', and are installed on the upper connector side on the upper connector body. A third fluid body ( 152'), including third monitoring parts 150'.

The left connector 131 ′ is subjected to a first indentation operation to enter or expose to the inside of the central body 110 ′, and the right connector 141 ′ moves into the central body 110 ′. A second appearance/disappearance operation of entering or exposing to the outside is performed, and a third appearance/disappearance operation of the upper connector 151 ′ entering or exposing to the inside of the central body 110 ′ is performed.

The 1-1 server (133') to the 3-2 server (154') are accommodated inside the central body 110' based on the first appearance/disappearance operation to the third appearance/disappearance operation. It can be stored to be protected from the outside, and the centralized management unit includes the 1-1 server 133', the 1-1 server 133' among the 1-1 server 133' to the 3-2 server 154'. A first operation mode in which the 1-2 server 134' is exposed to the outside of the central body 110', and the 1-1 server 133' to the 3-2 server 154 ') in a second operation mode in which the second-first server 143' and the second-second server 144' are exposed to the outside of the central body 110', and the second Among the 1-1 servers 133' to the 3-2 servers 154', the 3-1 server 153' and the 3-2 server 154' are the central body 110'. It is possible to operate in a third operation mode that performs an operation exposed to the outside of

The centralized management unit is a complex management module for performing a contamination control operation and support fixing for the first monitoring parts 130 ′, the second monitoring parts 140 ′, and the third monitoring parts 150 ′. further includes

Here, the complex management module includes a lower body 210' of the lowermost portion, a one-side vertical panel part 211' vertically installed on an upper side of the lower body 210', and the one-side vertical panel part 211') The 1-1 side horizontal body 212' installed horizontally on the top and the 1-1 side horizontal body 212' are provided at the end of the first side horizontal body 212' to discharge the cleaning solution for the one side server 123' for cleaning. The first 1-1 side cleaning body 213', the 1-1 side horizontal body 212' and the 1-1 side cleaning body 213' are provided between the 1-1 side cleaning body 213' and positioned upward. A first-first auxiliary cleaning body 214' for performing cleaning by discharging a cleaning solution for a 1-2-second server 134', and horizontally installed on the one-side vertical panel part 211', the first -The 1st and 2nd one-sided horizontal body 215' located on the upper side of the one-sided horizontal body 212', and the 3-1 server provided at the end of the 1-2 first-side horizontal body 215' The 1-2 one-side cleaning body 216' for performing cleaning by discharging the cleaning liquid to (153'), the 1-2 one-side horizontal body 215', and the 1-2 side cleaning body 216 ') and a 1-2 auxiliary cleaning body 217' for cleaning by discharging the cleaning liquid for the 1-1 server 133' located in the lower portion, and the lower body 210' The other side vertical panel part 221' vertically installed on the other upper side of The first 2-1 side cleaning body 223 ′ provided at the end of the one-sided horizontal body 222 ′ to perform cleaning by discharging the cleaning liquid for the other server 124 ′, and the 2-1 one-side horizontal body 223 ′ A 2-1 that is provided between the sieve 222' and the 2-1 one-side cleaning body 223' and performs cleaning by discharging a cleaning solution for the second-second server 144' positioned upward. Auxiliary cleaning body 224' and the 2-2 one-side horizontal body 225 installed horizontally on the other side vertical panel part 221' and located above the 2-1 one-side horizontal body 222' ') and the end of the first 1-2 side horizontal body 215' A 2-2 one-side cleaning body 226' provided in the 3-2 server 154' to perform cleaning by discharging the cleaning liquid for the 3-2 server 154', and the 2-2 one-side horizontal body 225' and the A 2-2 auxiliary cleaning body 227' which is provided between the 2-2 one-side cleaning bodies 226' and performs cleaning by discharging the cleaning solution for the 2-1 server 143' located below. includes

In addition, the complex management module is positioned between the one side vertical panel part 211' and the other side vertical panel part 221' in the upper part of the lower body 210' and is fixed through the central body 110'. The central fixing part 310', which is installed outside the one side vertical panel part 211' from the upper part of the lower body 210', and the first external height for supporting and fixing the one side vertical panel part 211' A second outer fixing part ( 511').

On the other hand, the central fixing part 310' is provided on the upper part of the lower body 210', and when the support panel 122' is mounted on the upper part, a pair of movable fixing bodies 3111' and 3112' provided on the upper part are provided. ) with a central fixing module 311 ′ for pressing and fixing both sides of the support panel 122 ′, and is provided on the upper left side of the lower body 210 ′ and is fixed to the center through a first interlocking body 312 ′. A one-side fixing module 313' connected to the module 311' and fixing the one-side vertical panel part 211' by pressing, and a second interlocking body 314' provided on the upper right side of the lower body 210' ) connected to the central fixing module 311 ′ and further includes the other fixing module 315 ′ for pressing and fixing the other side vertical panel part 221 ′.

The first outer fixing part 411' is installed in the upper part of the first inserting body 4111', which is partially inserted and mounted in the lower body 210', and the first inserting body 4111', and the A first opposing body 4112' facing and in contact with the one-side vertical panel part 211' is provided on an upper portion of the first opposing body 4112' and is a bottom surface portion above the one-side vertical panel part 211'. and a first upper panel 4113' in contact.

Here, the first insertion body 4111' supports and fixes the one-side vertical panel part 211' pressed by the one-side fixing module 313' in the opposite direction, and the first opposed body 4112' It is mounted and fixed to the one side vertical panel part 211' via a plurality of first entry structures (P11') provided in plurality in the height direction, and the first upper panel 4113' is the first provided in the lower part. 1 The lower entry structure (P12') is fixed to the upper side of the vertical panel part 211' through the medium.

The second outer fixing part 511' is installed in the upper part of the second inserting body 5111', which is partially inserted and mounted in the lower body 210', and the second inserting body 5111', and the A second opposing body 5112 ′ facing and in contact with the other side vertical panel unit 221 ′, is provided on the second opposing body 5112 ′ and is provided on the bottom surface of the other side vertical panel unit 221 ′ above the other side vertical panel unit 221 ′. and a second upper panel 5113 ′ that is in contact.

The second insertion body 5111' supports and fixes the other side vertical panel part 221' pressed by the other side fixing module 315' in the opposite direction, and the second opposing body 5112' It is mounted and fixed to the other side vertical panel part 221 ′ via a plurality of second entry structures P12 ′ provided in plurality in the height direction, and the second upper panel 5113 ′ is the second upper panel 5113 ′ provided on the lower side. 2 The lower entry structure (P22') is fixed to the upper side of the vertical panel portion (221') as a medium.

The first entry structure (P11'), the second entry structure (P12'), the first downward entry structure (P12'), and the second downward entry structure (P22') are respectively mounted and fixed in the forward direction or Based on the reverse rotation method, the fixing force is applied again to the one side vertical panel part 211' and the other side vertical panel part 221', respectively.

In addition, the centralized management unit, a first installation mode in which a plurality of symmetrically installed up and down on a predetermined installation target portion, a second installation mode in which a plurality of symmetrical installations are installed, and a third installation mode in which a plurality of symmetrical installations are vertically and horizontally installed. Each can be installed.

The one side vertical panel part 211' and the other side panel part 221' have the upper central body ( 110'), and with the one side server 123' and the other side server 124' removed on the support connector 121', the 1-1 side horizontal body 212' and the 2-1 one-side horizontal body 222' to press and fix the support connector 121', respectively, and the 1-2 one-sided horizontal body 215' and the 2-2 one-sided horizontal body Both sides of the third fluid 152' are respectively pressurized and fixed through 225'. The driving method of the physical components described above is based on a motor, an actuator, etc., and the forward and backward movement and rotational movement are made, and the shape and size of each component can be variously selected and provided according to the installation site and materials to be implemented. . Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: integration server
110: input unit
120: drawing conversion unit
130: basic information standardization unit
140: structure review unit
150: Bird's Eye View Composer
160: report writing unit
170: integration module
180: Estimation module

Claims (2)

As a building equipment for building integration system,
In the building integration system, integration is performed by the integration server that is linked with the integration DB and the estimate DB,
The building integration system further includes a centralized management unit for managing the integration server,
The integration server is one side server 123', the other side server 124', the 1-1 server 133', the 1-2 server 134', the 2-1 server 143', the second -2 server (144'), including a 3-1 server (153') and a 3-2 server (154'),
The centralized management unit,
a central body 110' for accommodating and cooling the integration servers inside;
It is installed under the central body 110' and is installed in the lower part of the central body 110' through a support connector 121' for cooling the integration servers, and the support connector 121' as a medium. A support panel 122' for supporting the central body 110', a plurality of one-side servers 123' installed to be positioned on one side of the support connector 121', and the support connector 121 ') and lower monitoring parts 120' including a plurality of other servers 124' which are located on the other side and are installed to be reversed from the one side server 123';
A left connector 131' installed on the left side of the central body 110', and a plurality of units installed to be positioned on the upper surface of the left connector 131' and cooled by the left connector 131' of the 1-1 server 133' and the lower surface of the left connector 131' and installed so as to be inverted from the 1-1 server 133', to the left connector 131' A first fluid comprising a plurality of first and second servers 134' cooled by the 1 monitoring parts (130'),
The right connector 141' is installed on the right side of the central body 110', and the right connector 141' is installed to be positioned on the upper surface of the right connector 141'. A plurality of 2-1 servers (143') that are cooled on 141',
A plurality of units located on the lower surface of the right connector 141' and installed to be reversed from the second-first server 143' and cooled on the right connector 141' by the right connector 141'. Second monitoring parts 140 including a 2-2 server 144' and a second fluid 142' installed on the right side of the central body 110' via the right connector 141'')Wow,
An upper connector 151' installed above the central body 110', and a plurality installed to be positioned on one side of the upper connector 151' and cooled on the upper connector by the upper connector of the 3-1 server 153' and the other side of the upper connector 151' and installed to be reversed from the 3-1 server 153', the upper connection body connects the upper side by the upper connector A plurality of 3-2 servers 154' cooled on a sieve, and a third fluid 152' installed on the upper side of the central body 110' via the upper connection body 151' Including the third monitoring parts (150'),
The left connecting body 131 'is the central body 110', the first out-and-out operation of entering or exposing to the outside is performed,
The right connecting body 141 'is the central body 110', the inside of the inside or exposed to the outside, the second appearance and exit operation is performed,
The upper connecting body 151 ′ is subjected to a third intrusion operation that enters into or is exposed to the outside of the central body 110 ′,
The 1-1 server 133' to the 3-2 server 154' are,
It can be stored so as to be accommodated inside the central body 110 ′ and protected from the outside based on the first appearance and withdrawal operation to the third appearance and withdrawal operation,
The centralized management unit,
Among the 1-1 servers 133' to 3-2 servers 154', the 1-1 server 133' and the 1-2 server 134' are the central body 110 ') a first operation mode for performing an operation exposed to the outside,
Of the 1-1 servers 133' to 3-2 servers 154', the 2-1 server 143' and the 2-2 server 144' are the central body 110 ') a second operation mode for performing an operation exposed to the outside,
Among the 1-1 servers 133' to 3-2 servers 154', the 3-1 server 153' and the 3-2 server 154' are the central body 110 ') that can be operated in the third operation mode to perform the operation exposed to the outside, the construction equipment of the building integration system. delete

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