阅读说明：本技术 用于创建数字建筑物模型的方法和装置 (Method and apparatus for creating digital building models ) 是由 O·采希林 于 2020-02-07 设计创作，主要内容包括：本发明涉及为了现有的建筑物创建数字建筑物模型的方法和装置,其中通过参考所述建筑物之外的官方锚点而为了所述建筑物的参考楼层设定建筑物中的位置点；其中在所设定的所述位置点处在所述参考楼层中安置机器可读标记；其中通过相对应设立的移动式读取设备(扫描设备)读取在参考楼层中的所述标记；其中基于所读取的所述标记的位置点对所述参考楼层的几何结构进行漂移补偿；其中针对在所述参考楼层中的房间以适合的标记法创建数字体积模型；并且其中在为了所述建筑物的基本上相同的楼层而创建数字体积模型的情况下将所述参考楼层的数字体积模型使用作为参考体积模型。(The invention relates to a method and a device for creating a digital building model for an existing building, wherein a location point in the building is set for a reference floor of the building by referring to an official anchor point outside the building; wherein a machine-readable marker is disposed in the reference floor at the set location point; wherein the markings in the reference floor are read by a correspondingly set mobile reading device (scanning device); wherein the geometry of the reference floor is drift compensated based on the read position point of the marker; wherein a digital volume model is created in suitable notation for a room in the reference floor; and wherein the digital volume model of the reference floor is used as a reference volume model in case a digital volume model is created for substantially the same floor of the building.)

1. Method for creating a digital building model (BIM) for an existing building (GB), the method comprising:

-setting location points (OPD 1, OPD 2) in the building (GB) for reference floors of the building by reference (Ref 1, Ref 2) to official anchor points (OAP 1-OAP 6) outside the building (GB);

-placing a machine-readable marker (M1-M3) in the reference floor at the set position point (OPD 1, OPD 2);

-reading the markers (M1-M3) in a reference floor by correspondingly set mobile reading devices (MG 1, AV1, MG2, AV 2), wherein the geometry of the reference floor is drift compensated based on the position points (OPD 1, OPD 2) of the read markers (M1-M3);

-creating in a digital building model (BIM), in particular a digital volume model, with suitable notation for the rooms in the reference floor;

wherein the digital volume model of the reference floor is used as a reference volume model when creating the digital volume model for substantially the same floor of the building (GB).

2. Method according to claim 1, wherein the reference volumetric model of the reference floor is used in creating an in particular digital volumetric model in a digital building model (BIM) for substantially the same floors of other buildings.

3. Method according to any of the preceding claims, wherein a Building Information Model (BIM) is created or extended based on the reference volume model of the reference floor.

4. The method according to any of the preceding claims, wherein the referencing (Ref 1, Ref 2) of the official anchor point (OAP 1-OAP 6) is done by Laser Tachymetry (LT) or by triangulation in order to set the position point (OPD 1, OPD 2) for the marker (M1-M3).

5. The method according to any of the preceding claims, wherein the machine-readable marking (M1-M3) comprises an optically readable marking.

6. The method according to any of the preceding claims, wherein the machine-readable label (M1-M3) comprises an RFID tag.

7. Apparatus for creating a digital building model (BIM) for an existing building (GB), the apparatus comprising:

-means for setting position points (OPD 1, OPD 2) in said building (GB) for reference floors of said building (GB) by reference (Ref 1, Ref 2) to official anchor points (OAP 1-OAP 6) outside said building (GB);

-a device (MG 1, AV1, MG2, AV 2) for reading machine-readable markers (M1-M3), wherein the machine-readable markers are placed at the set position points (OPD 1, OPD 2) in the reference floor, wherein the geometry of the reference floor is drift-compensated on the basis of the read position points (OPD 1, OPD 2) of the markers (M1-M3), and wherein a, in particular, digital volume model can be created in the digital building model (BIM) with suitable marking methods for the rooms in the reference floor and can be stored in a storage medium (DB);

-a processing device (S) set up correspondingly in order to use the digital volume model of the reference floor as a reference volume model when creating the digital volume model for a floor of the building (GB) or other building that is substantially the same as the reference floor.

8. Apparatus according to claim 7, wherein the storage medium (DB) is set up to be able to store the reference volume model as a Building Information Model (BIM).

9. The apparatus according to claim 7 or 8, wherein the storage medium (DB) is set up to: the digital volume model can be stored as a Building Information Model (BIM) for substantially the same floor as the reference floor.

Technical Field

The invention relates to a method and a device for creating a digital building model for an existing building.

Background

In a preparation phase for creating virtual images (digital twins) for buildings or virtual images for building clustering, existing buildings are detected with a scanner, in particular a laser scanner. When scanning a building, the measuring points in the building are detected and processed by suitable devices. However, these measuring points must be set in advance by the measurer and must be arranged in the building in a manner suitable for scanning.

In this case, the surveyor usually sets measuring points (anchor points, markings) by means of a tachymeter or a total station, wherein these measuring points are detected together during the scanning process. This preprocessing process requires almost as much time as the actual subsequent scanning process. The building site is "classified" by this measure, i.e. its site is located by means of coordinates. Furthermore, the system technical problem of the laser scanner is compensated by setting an anchor point inside the building. The device is prone to so-called "drift" in the case of long scanning surfaces (e.g. walls of large and long rooms), i.e. such that the actual laser spot line has a curvature. In the case of very large buildings, even the curvature of the earth can be effective here. In the case of using anchor points which are placed by the measurer and measured in advance, these anchor points can be used in subsequent processing on the software side for correction (drift correction). In addition to placing anchor points, the measurer also communicates information (particularly location) about the respective anchor point or marker to the service provider who scans the building next in the process. A scanning cart (e.g. a device from the NavVis company) that is movable in a building can use laser technology to detect, read and provide markings placed in the building for further processing digitally, in particular for use in a digital building information model of the corresponding building.

However, the known methods for determining measurement points in a building and the scan-in of measurement points for use in a digital building information model are laborious and time-consuming.

Disclosure of Invention

It is therefore an object of the present invention to provide an efficient method for using scanned-in measurement points for digital building information models.

This task is solved by a method for creating a digital building model (for example as a "digital twin") for an existing building, said method comprising:

setting a position point in the building (e.g. an anchor point in the building, a marker) for a reference floor of the building by reference to an official anchor point outside the building (in particular by optical reference and corresponding measurement, e.g. by a laser tachymeter or a total station) (e.g. by measuring in with a tachymeter (hindimessen));

-placing a machine-readable mark in the reference floor at the set location point;

reading the markings in the reference floor by means of a correspondingly equipped mobile reading device (scanning device, device of the NavVis company), wherein the geometry of the reference floor is drift-compensated on the basis of the position of the read markings;

-creating a, in particular digital, volume model in a digital Building Information Model (BIM) with suitable notation for the rooms in the reference floor; wherein the digital volume model of the reference floor is used as the reference volume model when creating the digital volume model for substantially the same floor of the building. With the mobile reader device (for example, a scanner device from the NavVis company), only a single floor has to be scanned as a reference floor and stored in the digital model. This is carried out by a suitable labeling method, for example, by the IFC labeling method (Industrial Foundation Class). The model of the reference floor is used to create a model for a structurally identical or substantially structurally identical floor. These structurally identical or substantially structurally identical floors do not have to be physically measured and scanned in, because a reference model of a reference floor is used for the modeling of these floors. This method is also effective if the reference model of the reference floor is not always able to be used for the other floors one-by-one and may need to be adapted manually by the modeler, e.g. by clipping. The mobile reading device (scanning device) advantageously provides a curvature-corrected three-dimensional point cloud with a text file, a photograph, sensor information, a geomagnetic field, and an access point for a reference floor, advantageously as a volumetric model for a room in the reference floor.

This method optimizes the on-site time flow, whereas the measuring staff, which has been commissioned up to now, only have to measure and set markings in partial areas, for example outside the building and in non-uniform structures within the building. The optimization potential of the method is increased in particular in the case of uniform buildings or building segments, for example frequently in the case of new office buildings. All the uniform floors are treated as "equivalent parts" (Gleichteil). It is sufficient to measure, mark and scan in one of these floors in the same way. All floors built "in duplicate" above and below after the scanning are recognized as "identical" by the processing software and the "corrective" measures in the case of the reference floors (which have been measured or marked) are transferred to these "identical" floors. Such (as viewed from the plan view) "wall lines" or "wall faces" (as viewed from the point cloud) are applied to the same type of floor if the wall has been straightened out in the reference floor after processing by the computing unit/software.

If an uninterrupted BIM model is used (building information model, together with the objects used and their properties), its information may further be included (object properties of the walls; e.g. prefabricated exterior walls with dimensions x, y, z and optionally other features). If further features are present in an uninterrupted manner in addition to the outer wall/floor plan, this can be, for example, an elevator zone and, if such a zone is recognized by the software in the scanned data, can also be included together, in order to automatically align the same floors "one by one" and model or incorporate them in the building model (BIM). For the floors, in particular for the reference floor, there are in each case (one or more for each floor) separate data sets which are aligned with one another in the further processing with the other data sets. This is advantageously done automatically, advantageously with corresponding rationality check criteria applied (e.g. the elevator doors for the elevators are located on the same vertical axis).

The position/coordinates (x and y) of the reference area determined by the measurer can be transferred to the "floor clone" established thereon. The z-axis information is also automatically determined and detected from other floors or defined, corrected or refined by BIM object information. In "building mezzanines," floor heights are usually indistinguishable (halls and attics are often different).

Advantageously, models are created for these floors by a user-friendly "drag and drop" method: it is thus possible to pile up the building in the model "in lenggao bricks". Thus, the floors of these floors may be given information in the model, for example by genetic mechanisms to inherit parameters (e.g. to inherit orientation and quality parameters, characteristics or attributes from a reference floor to a clone floor on the basis of the reference floor (i.e. a replica of the reference floor)).

Advantageously, the mobile reading device (scanning device) uses software to solve the SLAM problem (SLAM: Simultaneous Localization and Mapping). The mobile reading device (scanning device) can thus function as a mobile robot which, when reading the measuring points and the associated position coordinates, simultaneously creates a floor plan for the reference floor. Advantageously, the plan can be used as part of a Building Information Model (BIM).

A first advantageous embodiment of the invention consists in: the reference volumetric model of the reference floor is used for substantially the same floor of other buildings when creating the digital volumetric model. There are uniform building segments in each building. The invention realizes that: these unified building segments are treated as equal parts. It is therefore sufficient to measure and mark one of these floors in the same way. All floors built "in duplicate" above and below are recognized as "identical" after scanning by the processing software, and possible "corrective" measures in the case of reference floors (which have been measured or marked) are transferred to these "identical" floors. Such a "wall line" or "wall surface" (viewed from a plan view) is applied to the same type of floor if the wall has been straightened out in the reference floor after processing with the corresponding software by the computing unit.

Another advantageous embodiment of the invention consists in: the BIM model is created or extended based on a reference volumetric model of a reference floor. Building Information Modeling (Building Information Modeling) is a method for planning, creating and operating buildings in an integrated and thus optimized manner. The building data are stored and maintained in the form of machine-readable representations in a virtual, digital building model (BIM model (building information model)), for example in a corresponding database, which participants (architects, planners, building implementers, home service technicians, facility managers, etc.) can access. The digital building model can be created, for example, in IFC notation (industrial base class).

Another advantageous embodiment of the invention consists in: the reference to the official anchor point for setting the position point for the marking is made by laser tachymeter measurement or by triangulation. Measurements can be performed very accurately and quickly with an electronic tachymeter (total station). The determined data (for example in the form of three-dimensional measurement points) are advantageously loaded onto a corresponding storage medium or directly into a corresponding computer program or data model.

A further advantageous embodiment of the invention provides that the machine-readable marking comprises an optically readable marking (for example a QR code, a bar code). These machine-readable optical markings of these markings can be easily placed at accessible locations in a building and read by an optical detection unit (e.g. a laser scanner; e.g. a scanning device of the NavVis company). The detection unit may utilize a corresponding processing device (processor, software) to further process the read data (measurement points for position data) for, for example, drift compensation.

Another advantageous embodiment of the invention consists in: the machine-readable indicia comprises an RFID tag. The RFID tag may be placed, for example, under an ornament. Advantageously, the detection unit identifies the markers present in the building marked or referenced by the RFID tags.

The object is also solved by a device for creating a digital building model (digital twin) for an existing building, wherein the device comprises:

-means for setting (throughput) a location point in the building (anchor point in the building, mark) for a reference floor of the building by reference to an official anchor point outside the building;

-a device for reading a machine-readable marking placed at a set position point in a reference floor, wherein the geometry of the reference floor is drift-compensated on the basis of the position of the read marking, and wherein a, in particular digital, volume model can be created in a Building Information Model (BIM) for a room in the reference floor in a suitable marking method and the digital volume model can be stored in a storage medium;

a processing device set up accordingly in order to use the digital volume model of the reference floor as a reference volume model when creating the digital volume model for a floor of a building or other building that is substantially the same as the reference floor. In building planning or creation, the equipment required for implementing the device is usually present or can be easily accessed, for example, by entrusting the corresponding professional company (for example, to determine anchor points or to scan for signs).

Another advantageous embodiment of the invention consists in: the storage medium is designed to store the reference volume model as a BIM model. Thus, the reference volume model can be used directly for building data modeling. Building Information Modeling (Building Information Modeling) is a method for planning, creating and operating buildings in an integrated and thus optimized manner. The building data are stored and maintained in the form of machine-readable representations in a virtual, digital building model (BIM model), for example in a corresponding database, which participants (architects, planners, building executives, home service technicians, facility managers, etc.) can access. The digital building model can be created, for example, in IFC notation (industrial base class). There is a corresponding computer-supported tool (e.g., CAD tool) for building data modeling.

A further advantageous embodiment of the invention provides that the digital volume model for a floor substantially identical to the reference floor can be stored as a BIM model. There are uniform building segments in each building. The invention realizes that: these unified building segments are treated as equal parts. It is therefore sufficient to measure and mark one of these floors in the same way. The backup of the same floor as the reference floor in the BIM model enables: a BIM model is effectively created.

Drawings

The invention and advantageous embodiments of the invention are illustrated by way of example in the following figures. Wherein, here:

FIG. 1 shows an exemplary excerpt of a city plan with an exemplary officially measured anchor point;

FIG. 2 illustrates an exemplary apparatus for creating a digital building model for an existing building;

FIG. 3 illustrates exemplary markers for set location points in a building;

FIG. 4 illustrates an exemplary model view for an exemplary building; and

FIG. 5 illustrates an exemplary flow chart of a method for creating a digital building model for an existing building.

Detailed Description

FIG. 1 shows an exemplary excerpt of a city plan with exemplary official measured anchor points OAP1-OAP 4. Such anchor points OAP1-OAP4 are determined or used in the specialist field of geodetics, in particular in the specialist field of engineering geodetics, for example for topographic, cadastral or architectural measurements. Anchor points OAP1-OAP4 are also referred to as measurement points or stations. The anchor point may be set, for example by triangulation, to a triangular point with corresponding coordinates. Depending on the application, anchor points are also referred to as elevation control points, geodetic fixed points, elevation markers, planar control points, etc. These anchor points OAP1-OAP4 may be defined, for example, as plane coordinates in the gaussian Krigger coordinate system or in the UTM (Universal Transverse Mercator) coordinate system.

The location points (markers) are set in the building, for example by measuring the official anchors OAP1-OAP4 into the building and by referencing the official anchors OAP1-OAP 4. These location points (markings) in the building are marked by corresponding markers (e.g. QR codes). These location points (markers) in the building can be read, evaluated and stored into the building information model by a suitable reading device, for example a scanning device of the NavVis company.

Fig. 2 shows an exemplary apparatus for creating a digital building model (digital twin) BIM for an existing building GB. The device includes:

-a device LT for setting (throughput) a position point (anchor point in building, mark) in building GB for a reference floor of building GB by referring to official anchors OAP5, OAP6 outside Ref1, Ref2 building GB;

-devices MG1, AV1, MG2, AV2 for reading machine-readable markers M1, M2 placed at set position points in a reference floor, wherein the geometry of the reference floor is drift compensated based on the read positions of the markers M1, M2, and wherein a digital volume model BIM can be created for the rooms in the reference floor in a suitable marking method and can be stored in a storage medium DB;

a processing device S set up accordingly in order to use the digital volume model BIM of the reference floor as a reference volume model when creating the digital volume model for a floor of the building GB or other building that is substantially the same as the reference floor.

The model of the reference floor is used to create a model for a structurally identical or substantially structurally identical floor. These structurally identical or substantially structurally identical floors do not have to be physically measured and scanned in, because a reference model of a reference floor is used for the modeling of these floors. This method is also effective if the reference model of the reference floor is not always able to be used for the other floors one-by-one and may need to be adapted manually by the modeler, e.g. by clipping. The mobile reading devices (scanning devices, carts, drones) MG1, MG2 advantageously provide a curvature-corrected three-dimensional point cloud with text files, photographs, sensor information, geomagnetic fields, and access points for reference floors.

The storage medium DB is advantageously designed to be able to store the reference volume model as a BIM model BIM. This is carried out by means of suitable labeling methods, for example by means of the IFC labeling method ((Industrial Foundation Class)).

Advantageously, the storage medium DB is set up to: the digital volume model can be stored as a BIM model BIM, for example in IFC notation (industrial Foundation Class) for substantially the same floor as the reference floor. By reference to Ref1, Ref2 official anchors OAP5, OAP6, for example by laser tachymeter LT or triangulation: position points M1 and M2 (anchor points and marks in the building) are set in the building GB. With a mobile reader MG1 (for example a scanner from the NavVis company) only a single floor has to be scanned as reference floor and stored in the digital model. The mobile reading device MGI comprises for example an optical pick-up device AV1 for reading machine-readable markers M1, M2 arranged at set points in a reference floor. In principle, it is also possible to use a drone (unmanned aircraft) MG2 with a corresponding recording device AV2 for reading the machine-readable markers M1, M2 placed at the set points. The mobile reading apparatuses MG1, MG2 may move independently and autonomously in the building or in a manner controlled by the operator B.

As mobile device MG1, a Trolley (Trolley) with a corresponding measuring instrument AV1, such as a Trolley M3 from the company Navvis GmbH, for example, can be used, wherein the Trolley is pushed by an operator B through the building GB. As a mobile device for detecting the setpoint state, a mobile robot may also be used, for example a driving robot with a corresponding measuring device, wherein the driving robot autonomously or semi-autonomously travels everywhere in the corresponding building.

As mobile device MG2 for detecting the setpoint state, a drone (unmanned aircraft) with a corresponding measuring device can also be used, which autonomously moves in and/or around the building GB. Advantages in the application of drone MG2 are in particular: can be used very easily in stairs or staircases. The drone may be used autonomously (with corresponding programming and control), semi-autonomously, or manually (i.e., in a manner controlled by the operator).

The location point data (location points) OPD1, OPD2 of the markers M1, M2 read by the recording devices AV1, AV2 may be forwarded to the server S via suitable communication connections KV1, KV2 (e.g. via corresponding radio connections, WLAN, internet, mobile radio connections). All the position point data OPD1, OPD2 of the read markers in the building GB can be in the server S as a point cloud. The server S (computer with corresponding processing and storage devices) analyzes the point cloud and maps it into the building information model BIM, for example in the form of a digital volume model.

One advantage of the present invention is that a reference volumetric model of a reference floor is used in creating a digital volumetric model for substantially the same floor of a building. There are uniform building segments in each building. The invention makes it possible in particular to treat these unified building segments as "peers". It is therefore sufficient to measure and mark one of these floors in the same way.

The building information model BIM is stored in a suitable database DB, for example in an in-memory database, which enables fast access. Advantageously, this server S is implemented in a cloud infrastructure C.

Fig. 3 shows an exemplary marker M3 for a set location point in a building. Advantageously, the marking M3 comprises a machine-readable or optically readable marking (e.g. QR code, barcode). These machine-readable optical markings of these markings can be easily placed at accessible locations in a building and read by an optical detection unit (e.g. a laser scanner; e.g. a scanning device of the NavVis company). The detection unit may utilize a corresponding processing device (processor, software) to further process the read data (measurement points for position data) for, for example, drift compensation.

Advantageously, the marking M3 is suitable for solving the SLAM problem (SLAM: Simultaneous Localization and Mapping) the mobile reading device (scanning device) can thus function as a mobile robot which simultaneously creates a plan for the corresponding building floor when reading the measurement points (markings) and the associated position coordinates.

Advantageously, the marker M3 comprises a cross-shaped marking for precise positioning (and comprises an arrow for orientation (e.g. orientation in the cardinal direction)). Advantageously, the tag M3 comprises a unique identifier such as (ID number). Advantageously, the marker M3 is composed of a robust material that can also be used on the outer wall of a building. Advantageously, the marker M3 comprises bibliographic data (e.g. point in time of location reference, point in time of placement, responsible company, responsible operator, official anchor point based on which the reference is made).

FIG. 4 illustrates exemplary model views SM1-SM4 for an exemplary building on an exemplary operator interface UI. The exemplary user interface UI may be shown, for example, on a display (e.g., a touch screen) of a computer display. Exemplary model views SM1-SM4 illustrate different views or representation types of the digital volume model as aspects (portions) of the building information model. These views SM1-SM4 show exemplary 2D or 3D views of the building model. The position coordinates of the model are based on markings read and evaluated when scanning the buildings belonging to the model. The operation interface UI includes a menu bar ML for user input or user selection.

FIG. 5 illustrates an exemplary flow chart of a method for creating a digital building model for an existing building. The method comprises the following steps:

-setting position points in the building (anchor points in the building, marks) for reference floors of the building by referring to official anchor points outside the building (through input);

-placing a machine-readable mark in the reference floor at the set location point;

reading the markings in the reference floor by means of a correspondingly equipped mobile reading device (e.g. a scanning device, a Navis device from NavVis corporation), wherein the geometry of the reference floor is drift-compensated on the basis of the position of the read markings;

-creating a, in particular digital, volume model in a digital building model (BIM) with suitable notation for the rooms in the reference floor; wherein the digital volume model of the reference floor is used as the reference volume model when creating the digital volume model for substantially the same floor of the building. The setting of the location points in the building (anchor points in the building, markings) is carried out by reference to official anchor points, for example by means of laser tachymeters or by triangulation.

With mobile reading devices (for example, the scanning device from the NavVis company), only a single floor has to be scanned as a reference floor and stored in the digital model. This is carried out by a suitable labeling method, for example, by the IFC labeling method (Industrial Foundation Class). The model of the reference floor is used to create a model for a structurally identical or substantially structurally identical floor. These structurally identical or substantially structurally identical floors do not have to be physically measured and scanned in, because a reference model of a reference floor is used for the modeling of these floors. This method is also effective if the reference model of the reference floor is not always able to be used for the other floors one-by-one and may need to be adapted manually by the modeler, e.g. by clipping. The mobile reading device (scanning device) advantageously provides a curvature-corrected three-dimensional point cloud with text files, photographs, sensor information, geomagnetic field, and access points for reference floors.

Exemplary contents of the point cloud file are:

the point cloud file can be translated or converted into a notation of a building information model (BIM model) by a corresponding converter.

Advantageously, the BIM model is created or extended, for example in IFC notation, based on a reference volume model of a reference floor.

The method according to the invention can be implemented with correspondingly set-up hardware components and software components (e.g. processor unit, storage device, input/output unit, software program). The method according to the invention achieves in particular: digital twins (digital twining) are optimally and efficiently transformed or created. This is achieved in particular in building creation and in building management: cost and time position improvements for sales units, in particular, implemented and supplied.

The invention relates to a method and a device for creating a digital building model for an existing building, wherein a location point in the building is set for a reference floor of the building by referring to an official anchor point outside the building; wherein a machine-readable marker is disposed in the reference floor at the set location point; wherein the markings in the reference floor are read by a correspondingly set mobile reading device (scanning device), wherein the geometry of the reference floor is drift-compensated on the basis of the position of the read markings; wherein a digital volume model is created with suitable notation for a room in a reference floor; and wherein the digital volume model for the reference floor is used as the reference volume model when creating the digital volume model for substantially the same floor of the building.

List of reference numerals:

MAP city plan

OAP1-OAP6 official anchor point

LT laser stadiometer

M1-M3 marker

GB building

C cloud

S server

DB database

BIM building information model

KV1 and KV2 communication connection

B operator

MG1, MG2 mobile equipment

AV1, AV2 recording apparatus

OPD1, OPD2 position points

Ref1, Ref2 reference

ML menu bar

UI operating interface

SM1-SM4 Site Model (Site Model) (plan view Model).