EP3928239A1 - Method and arrangement for creating a digital building model - Google Patents

Abstract

The invention relates to a method and to an arrangement for creating a digital building model for an existing building, wherein: location points in the building are defined by referencing official anchor points outside the building for a reference storey of the building; machine-readable markers in the reference storey are attached to the defined location points; the markers in the reference storey are read in by a correspondingly configured mobile reading device (scanning device), wherein on the basis of the location position of the read-in markers a drift compensation of the geometry of the reference storey is carried out; a digital volume model for the rooms in the reference storey is created in a suitable notation; and the digital volume model of the reference storey is used as the reference volume model during the creation of digital volume models for substantially identical storeys of the building.

Description

Method and arrangement for creating a digital building model

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

Prior to the creation of a virtual image for a building (digital twin, digital twin) or for a collection of buildings, existing buildings are recorded with scanners, in particular laser scanners. When a building is scanned, measurement points in the building are recorded and processed using suitable devices. However, these measurement points must first be determined by a surveyor and attached in the building in a way that is suitable for scanning.

The surveyor usually sets measurement points (anchor points, markers) with the help of a tachymeter or a total station, which are also recorded during the scanning process. This preparatory process takes about the same amount of time as the actual subsequent scan process. With this measure, the building location is "northed", i.e. its location is placed by means of coordinates. Furthermore, the system-technical problems of a laser scanner are compensated for by setting anchor points inside the building Spaces) to the so-called "drift", ie the actual laser point straight line has a curvature. In the case of very large buildings, the curvature of the earth even comes into play here. When using anchor points that have been placed and measured beforehand by a surveyor, these can be used in post-processing by the software for correction (drift correction). In addition to the placement of the anchor points, the surveyor passes on the information (in particular the positions) to the respective anchor points or markers to the service providers who follow the process and who carry out the scan of the building. Scan trolleys that can be moved in the building (e.g. devices from NavVis) can be used in the building with laser technology Detect attached markers, put them in, and make them available for further digital processing, in particular for use in a digital building information model for the corresponding building.

The known procedure for determining the survey points in a building and the scanning of the survey points for use in a digital building information model is laborious and time-consuming.

It is therefore the object of the present invention to provide an efficient method for the use of scanned measurement points for a digital building information model.

The task is solved by a method for creating a digital building model (e.g. as a "digital twin", i.e. as a digital twin) for an existing building, the method comprising:

- Determination of location points (e.g. markers, anchor points in the building) in the building by referencing (in particular by optical referencing and corresponding measurement e.g. by a laser total station or a total station) of official anchor points outside the building (e.g. by measuring with a total station) for a reference floor of the building;

- Attachment of machine-readable markers in the reference floor at the defined location points;

- Reading in of the markers in the reference storey by a suitably equipped mobile reading device (scanning device, e.g. a device from NavVis), with drift compensation of the geometry of the reference storey taking place based on the position of the read markers;

- Creation of a particularly digital volume model for the rooms on the reference floor in a building information model (BIM) in a suitable notation, the digital Volume model of the reference floor is used as a reference volume model when creating digital volume models for essentially identical floors of the building. With the mobile reading device (e.g. scanning device from NavVis) only a single floor needs to be scanned as a reference floor and stored in a digital model. This is done in a suitable notation, e.g. in IFC (Industry Foundation Class) notation. The model of the reference storey is used to create the model for identical or essentially identical floors. The structurally identical or essentially structurally identical floors do not have to be physically measured and scanned, since the reference model of the reference floor is used for their modeling. This procedure is still efficient even if the reference model of the reference storey cannot always be used one-to-one for a further storey, and manual adjustments (eg by tailoring) may be necessary by a modeler. The mobile reading device (scanning device) advantageously supplies a curvature-corrected 3-dimensional point cloud with photos, sensor information, earth's magnetic field, access points and text file for the reference storey. With advantage as a volume model for the rooms on the reference floor.

The process optimizes the on-site timing; the surveyor, who has been used consistently up to now, only needs to measure and set marks in sub-areas, e.g. outside the building, as well as the non-uniform structures within the building. The optimization potential of the present method can be increased in particular in the case of uniform buildings or building segments, for example often new office buildings. All uniform floors are treated as "the same part". It is sufficient to measure, mark and scan one of these uniform floors. All floors which are "duplicated" The processing software recognizes them as "identical" after the scan, and the corrective measures that were marked on the reference floor (which was measured I) are transferred to these "identical" floors. If in the reference floor after the Processing by a computing unit / software, a wall has been straightened, such a "wall line" (from the floor plan) or "wall area" (point cloud observation) is applied to the floors of the same type.

If a continuous BIM model (building information model, with use of the objects and their properties, is used, their information can continue to flow into it (object properties of walls; e.g. prefabricated outer wall with dimensions xyz and optionally other features) Outer walls / floor plan further features consistently available, this could be the elevator area, for example - and if such a feature is recognized in the scanned data by software, this feature can also be included in order to automatically identify similar floors "floor by floor" and to be modeled or integrated in the building model (BIM). For each floor, especially for the reference floor, there are separate data sets (one or more per floor), which are aligned with the other data sets during further processing - follows automatically with advantage, with advantage using the appropriate Pla usibility criteria (e.g. Elevator doors for an elevator are in the same vertical axis).

The positions / coordinates of the reference areas determined by the surveyor can be transferred to the "floor clones" based on them (x and y). The z-axis information could also be determined and recorded automatically on the basis of additional floors. through BIM object information be defined, corrected, or refined. Floor heights usually do not differ "in the building sandwich" (lobby and loft are often different).

The models for the storeys are advantageously created using a user-friendly "drag and drop" process: a building can thus be piled up in the model "like a Lego brick". Information can thus be given to the storey layers in the model, e.g. through an inheritance mechanism that inherits parameters (e.g. alignment and quality parameters, properties, or attributes from the reference floor to the clone floors based on them (i.e. the copies of the reference floor).

The mobile reading device (scan device) advantageously uses software to solve SLAM problems. (SLAM: Simultaneous Localization and Mapping, Simultaneous Position Determination and Map Creation). The mobile reading device (scanning device) can thus function as a mobile robot that simultaneously creates a plan for the reference storey when reading in the measuring points and the associated location coordinates. The plan can advantageously be used as part of the building information model (BIM).

A first advantageous embodiment of the invention lies in the fact that the reference volume model of the reference storey is used when creating digital volume models for essentially identical storeys of a further building. There are uniform building segments in every building. The present invention makes it possible, among other things, to treat these uniform building segments as identical parts. It is therefore sufficient to measure and mark one of these uniform floors. All floors that are "duplicated" on top of each other are recognized as "identical" after scanning by the processing software, and possibly corrective Measures which are transferred to these "identical" floors on the reference floor (which was measured or marked). If a wall was straightened in the reference floor after processing by a computer unit with appropriate software, such a "wall line" (for basic crack observation) or a "wall surface" (with regard to point cloud observation) applied to the floors of the same type.

Another advantageous embodiment of the invention is that a BIM model is created or expanded based on the reference volume model of the reference floor. Building Information Modeling is a process for the integrated and thus optimized planning, creation and operation of buildings. Building data is stored and maintained in a virtual, digital building model (BIM model, building information model) in a machine-readable notation, e.g. in a corresponding database to which those involved (architect, planner, building contractor, building technology, facility management, etc.) can access. The digital building model can e.g. be drawn up in IFC (Industry Foundation Classes) notation.

A further advantageous embodiment of the invention is that the referencing of the official anchor points for establishing the location points for the markers is carried out by a laser total station measurement or by triangulation. With electronic total stations, the measurements can be carried out very precisely and quickly. The determined data (for example in the form of three-dimensional measuring points) are advantageously loaded onto appropriate storage media or directly into appropriate computer programs or data models. A further advantageous embodiment of the invention is that the machine-readable markers include an optically readable identifier (for example QR code, barcode). The machine-readable optical identifiers of the markers can easily be attached to accessible locations in the building and read in by an optical acquisition unit (eg laser scanner; eg scanning device from NavVis). The acquisition unit can use appropriate processing means (processor, software) to further process the read-in data (measurement points for location data), for example to compensate for drift.

Another advantageous embodiment of the invention is that the machine-readable markers comprise an RFID tag. RFID tags can e.g. be mounted under plaster. The registration unit advantageously recognizes markers that are present in the building and that are identified or referenced by RFID tags.

The task is also achieved by an arrangement for creating a digital building model (digital twin) for an existing building, the arrangement comprising:

- Means for establishing location points (markers, anchor points in the building) in the building by referencing official anchor points outside the building (by measuring into) for a reference floor of the building;

- Means for reading in machine-readable markers attached to the specified location points in the reference floor, with a drift compensation of the geometry of the reference floor taking place based on the position of the read-in marker, and a particularly digital volume model for the rooms in the reference floor in one Building information model (BIM) can be created in a suitable notation and stored in a storage medium; appropriately set up processing means in order to use the digital volume model of the reference floor as a reference volume model when creating digital volume models for floors of the building or of another building that are essentially identical to the reference floor. The resources required to implement the arrangement are usually available when planning or creating a building, or they can be easily accessed, for example by commissioning appropriate specialist companies (for example for measuring anchor points or scanning the markers).

Another advantageous embodiment of the invention is that the storage medium is set up so that the reference volume model can be stored as a BIM model. This means that the reference volume model can be used directly for building data modeling. Building information modeling is a process for the integrated and thus optimized planning, creation and operation of buildings. Building data is stored and maintained in a virtual, digital building model (BIM model) in a machine-readable notation, e.g. in a corresponding database to which the parties involved (architect, planner, construction contractor, building services, facility management, etc.) can access. The digital building model can e.g. be created in IFC (Industry Foundation Classes) notation. There are corresponding computer-aided tools (e.g. CAD tools) for modeling building data.

A further advantageous embodiment of the invention is that the digital volume models for the floors that are essentially identical to the reference floor can be stored as a BIM model. There are uniform building segments in every building. The present invention makes it possible, inter alia, to treat these uniform building segments as identical parts. It is therefore sufficient to measure and mark one of these uniform floors. The storage of floors identical to the reference floor in the BIM model enables the BIM model to be created efficiently.

The invention and advantageous embodiments of the present

Invention are explained using the example of the following figure. It shows:

1 shows an exemplary excerpt from a city map

exemplary officially measured anchor points,

FIG. 2 shows an exemplary arrangement for creating a digital building model for an existing building,

3 shows an exemplary marker for a specified one

Location in a building,

4 shows exemplary model views for an exemplary

Building, and

FIG. 5 shows an exemplary flow diagram for a method for creating a digital building model for an existing building.

FIG. 1 shows an exemplary excerpt from a city map with exemplary officially measured anchor points OAP1-OAP4. Such anchor points OAP1-OAP4 are determined or used in the field of geodesy, in particular engineering geodesy, for example for land surveying, cadastral surveying or building surveying. Anchor points OAP1 - OAP4 are also referred to as survey points or measuring points. she can for example be defined as a trigonometric point with corresponding coordinates by triangulation. Depending on the application, anchor points are also referred to as height control point, geodetic control point, height marker, position control point, etc. The anchor points OAP1 - OAP4 can be defined, for example, as position coordinates in a Gauss-Krüger coordinate system or in a UTM (Universal Transverse Mercator) coordinate system.

By referencing the official anchor points OAP1 - OAP4, e.g. By measuring official anchor points OAP1 - OAP4 into a building, location points (markers) in the building are determined. These location points (markers) in the building are marked with appropriate identifiers (e.g. QR code). These location points (markers) in the building can be read in, evaluated and stored in a building information model using suitable reading devices (e.g. scanning device from NavVis).

FIG. 2 shows an exemplary arrangement for creating a digital building model (digital twin) BIM for an existing building GB.

The arrangement includes:

- Means LT for establishing location points (markers, anchor points in the building) in the building GB by referencing Ref1, Ref2 of official anchor points OAP5, OAP6 outside the building GB (by measuring into) for a reference floor of the building GB;

Means MG1, AV1, MG2, AV2 for reading in machine-readable markers M1, M2 attached to the specified location points in the reference story, with a drift compensation of the geometry of the reference story based on the position of the read-in markers M1, M2 takes place, and being a digital Volume model BIM for the rooms on the reference floor can be created in a suitable notation and stored in a storage medium DB;

Correspondingly set up processing means S to use the digital volume model BIM of the reference floor as a reference volume model when creating digital volume models for floors of the building GB or of another building that are essentially identical to the reference floor.

The model of the reference storey is used for the creation of a model for identical or essentially identical storeys. The structurally identical or essentially structurally identical floors do not have to be physically measured and scanned, since the reference model of the reference floor is used for their modeling. This procedure is also efficient if the reference model of the reference floor cannot always be used one-to-one for a further floor, and manual adjustments (e.g. by tailoring) may be necessary by a modeler. The mobile reading device (scanning device, trolley, drone) MG1, MG2 advantageously provides a curvature-corrected three-dimensional point cloud with photos, sensor information, geomagnetic field, access points and text file for the reference floor.

The storage medium DB is advantageously set up so that the reference volume model can be stored as a BIM model BIM.

This is done in a suitable notation, e.g. in IFC notation (Industry Foundation Class).

The storage medium DB is advantageously set up so that the digital volume models for the floors that are essentially identical to the reference floor can be stored as BIM model BIM, for example in IFC notation (Industry Foundation Class). The establishment of location points M1, M2 (markers, anchor points in the building) in the building GB by referencing Ref1, Ref2 of official anchor points OAP5, OAP6 is carried out, for example, by a laser tachymeter LT or by triangulation. With a mobile reading device MGI (e.g. scanning device from NavVis) only a single floor has to be scanned as a reference floor and stored in a digital model. The mobile reading device MGI comprises, for example, an optical recording device AV1 for reading in machine-readable markers M1, M2 attached to the fixed location points in the reference storey. In principle, a drone (unmanned aircraft) MG2 with a corresponding recording device AV2 can also be used to read in machine-readable markers M1, M2 attached to the defined location points. The mobile reading devices MG1, MG2 can move independently autonomously in the building, or controlled by an operator B.

The mobile device MG1 can e.g. a trolley with appropriate measuring equipment AV1 can be used, which is pushed through the building GB by an operator B, e.g. the M3 trolley from Navvis GmbH. A mobile robot can also be used as a mobile device for recording the target state, e.g. a driving robot with appropriate measuring devices that drives around autonomously or semi-autonomously in the relevant building.

A drone (unmanned aircraft) with appropriate measuring devices, which moves autonomously in the building GB and / or around the building GB, can also be used as the mobile device MG2 for recording the target state. The advantage of using an MG2 drone is, among other things, that it can be used very easily in stairs or stairwells. A drone can be used autonomously (with appropriate programming and control), semi-autonomously, or manually (ie controlled by an operator). The location data (location points) OPD1, OPD2 of the markers M1, M2 read by the recording devices AV1, AV2 can be forwarded to a server S via suitable communication links KV1, KV2 (for example, via appropriate radio links, WLAN, Internet, cellular connection). The location point data OPD1, OPD2 of all read-in markers in the building GB can be sent to the server S as point clouds. The Sever S (computer with appropriate processing and storage means) analyzes the point cloud and maps it in a building information model BIM, for example in the form of a digital volume model.

An advantage of the invention is that a reference volume model of a reference floor is used when creating digital volume models for essentially identical floors of the building. There are uniform building segments in every building. The present invention enables i.a. to treat these uniform building segments as identical parts. It is therefore sufficient to measure and mark one of these uniform floors.

The building information model BIM is stored in a suitable database DB, e.g. in an in-memory database, which enables quick access. The server S is advantageously implemented in a cloud infrastructure C.

FIG. 3 shows an exemplary marker M3 for a defined location in a building. The marker M3 advantageously comprises a machine-readable or an optically readable identifier (for example QR code, barcode). The machine-readable optical identifiers of the markers can easily be attached to accessible places in the building and read in by an optical acquisition unit (eg laser scanner; eg scanning device from NavVis). The acquisition unit can with appropriate processing means (processor, software) to the processed data (measurement points for location data), for example to compensate for drift.

The M3 marker is advantageously suitable for solving SLAM problems (SLAM: Simultaneous Localization and Mapping, simultaneous position determination and map creation). The mobile reading device (scanning device) can thus function as a mobile robot that simultaneously creates a plan for the corresponding building floor when reading in the measuring points (markers) and the associated location coordinates.

The marker M3 advantageously includes a cross symbol for exact localization and an arrow for orientation (e.g. orientation according to the compass direction). The marker M3 advantageously includes a unique identification code (e.g. ID number). The M3 marker is advantageously made of a robust material that can also be used on the outside wall of a building. The marker M3 advantageously includes bibliographic data (e.g. time of location referencing, time of attachment, responsible company, responsible processor, official anchor point on the basis of which the referencing took place).

FIG. 4 shows exemplary model views SM1-SM4 for an exemplary building on an exemplary user interface UI. The exemplary user interface UI can be shown, for example, on a display (eg touchscreen) of a computer display. The exemplary model views SM1-SM4 show different views or types of representation of digital volume models as aspects (parts) of a building information model. The views SM1 - SM4 show exemplary 2D or 3D views of the building model. The location coordinates of the model are based on the markers that were read in and evaluated when the building belonging to the model was scanned. The user interface UI comprises a menu bar ML for user entries or user selections. FIG. 5 shows an exemplary flow chart for a method for creating a digital building model for an existing building. The procedure includes:

- Determination of location points (markers, anchor points in the building) in the building by referencing official anchor points outside the building (by measuring into) for a reference floor of the building;

- Attachment of machine-readable markers in the reference floor at the defined location points;

- Reading in the markers in the reference floor by a suitably equipped mobile reading device (e.g. scanning device, navigation device from NavVis), with drift compensation of the geometry of the reference floor taking place based on the position of the markers read in;

- Creation of a particularly digital volume model in the digital building model (BIM) for the rooms on the reference floor in a suitable notation; wherein the digital volume model of the reference storey is used as a reference volume model when creating digital volume models for essentially identical storeys of the building. The determination of location points (markers, anchor points in the building) in the building by referencing official anchor points takes place e.g. by a laser total station or by triangulation.

With a mobile reading device (eg scanning device from the NavVis company) only a single floor has to be scanned as a reference floor and stored in a digital model. This is done in a suitable notation, e.g. in IFC (Industry Foundation Class) notation. The model of the reference storey is used to create the model for identical or essentially identical floors. The structurally identical or essentially structurally identical floors do not have to be physically measured and scanned, as their Modeling the reference model of the reference storey can be used. This procedure is still efficient even if the reference model of the reference storey cannot always be used one-to-one for a further storey, and manual adjustments (eg by tailoring) may be necessary by a modeler. The mobile reading device (scanning device) advantageously supplies a curvature-corrected three-dimensional point cloud with photos, sensor information, geomagnetic field, access points and text file for the reference floor.

Sample content of a point cloud file: ply

format ascii 1.0

element vertex 363

property float x

property float y

property float e.g.

property float scalar_scan_time_from_start

property float scalar_roll

property float scalar_pitch

property float scalar_yaw

property uint scalar_confidence_metric

comment UTC time at start 1528458354.284151

end_header

-0.000374 -0.000614 0.000247 10.016065 -0.000821 -0.037225 - 0.013847 0

0.001295 0.016669 -0.016714 10.916214 0.000584 -0.048837 - 0.016327 26907

-0.000672 0.002347 0.001899 11.816589 -0.000535 -0.039471 - 0.015925 50000

-0.001323 0.009148 -0.010352 12.716636 -0.001709 -0.044635 - 0.016510 50000

0.001556 0.003548 -0.001648 13.616427 0.000603 -0.036830 - 0.013826 50000 0.004702 0.013384 .008795 14.541398 0.004530 0.03876

0.013606 50000

0.001446 0.004157 0.000075 15.466380 0.003677 0.04219

0.014400 50000

0.005786 0.004428 .008930 16.466257 0.002561 0.04060

0.013492 50000

0.003914 0.002555 0.002479 17.466155 0.004913 0.03935

0.013419 50000

0.003208 0.002262 .003176 18.466278 0.004496 0.04410

0.012279 50000

.000103 0.005178 0.004468 19.466257 0.006104 0.04361 0.010986 50000

0.003960 0.004793 0.007028 20.466523 0.007117 0.041868 0.002362 50000

A point cloud file can be translated or converted into the notation of a building information model (BIM model) using an appropriate converter.

A BIM model is advantageously created or expanded based on the reference volume model of the reference floor, e.g. in IFC notation.

The method according to the invention can be implemented with appropriately set up hardware and software components (for example processor unit, storage means, input / output units, software programs). The method according to the invention enables, in particular, an optimized and efficient implementation or creation of a digital twin (digital twin). In building construction and building management, this enables, among other things, an improvement in costs and time for, among other things, executing and offering sales units. The invention relates to a method and an arrangement for creating a digital building model for an existing building, location points in the building being established for a reference floor of the building by referencing official anchor points outside the building; machine-readable markers are attached to the specified location points on the reference floor; the markers in the reference storey being read in by a suitably set up mobile reading device (scanning device), the geometry of the reference storey being compensated for drift based on the location of the markers read in; a digital volume model for the rooms on the reference floor is created in a suitable notation; and wherein the digital volume model of the reference storey is used as a reference volume model when creating digital volume models for essentially identical storeys of the building.

Reference number

MAP city map

OAP1 - OAP 6 Official anchor point LT laser total station

M1 - M3 markers

GB building

C cloud

S server

DB database

BIM building information model

KV1, KV2 communication link B operator

MG1, MG2 Mobile device

AV1, AV2 pick-up device

OPD1, OPD2 location point

Ref1, Ref2 referencing

ML menu bar

UI user interface

SM1 - SM4 Site Model (plan model)

Claims

Claims

1. Procedure for creating a digital building model (BIM) for an existing building (GB), the procedure includes:

Determination of location points (OPD1, OPD2) in the building (GB) by referencing (Ref1, Ref2) of official anchor points (OAP1 - OAP6) outside the building (GB) for a reference floor of the building (GB);

Attachment of machine-readable markers (M1 - M3) in the reference floor at the defined location points (OPD1, OPD2);

Reading of the markers (M1 - M3) in the reference floor by a suitably set up mobile reading device (MG1, AV1, MG2, AV2), whereby, based on the location points (OPD1, OPD2) of the read markers (M1 - M3), a drift compensation of the geo - the reference floor is measured;

Creating an in particular digital volume model in the digital building model (BIM) for the rooms on the reference floor in a suitable notation;

wherein the digital volume model of the reference floor is used as the reference volume model when creating digital volume models for essentially identical floors of the building (GB).

2. The method according to claim 1, wherein the reference volume model of the reference storey is used when creating, in particular, digital volume models in a digital building model (BIM) for essentially identical storeys of a further building.

3. The method according to any one of the preceding claims, wherein a building information model (BIM) is created or expanded based on the reference volume model of the reference floor.

4. The method according to any one of the preceding claims, wherein the referencing (Ref1, Ref2) of the official anchor points (OAP1 - OAP6) to define the location points (OPD1, OPD2) for the markers (Ml - M3) by a laser total station measurement ( LT) or by triangulation.

5. The method according to any one of the preceding claims, wherein the machine-readable markers (M1-M3) comprise an optically readable identifier.

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

7. Arrangement for creating a digital building model (BIM) for an existing building (GB), the arrangement includes:

Means for determining location points (OPD1, OPD2) in the building (GB) by referencing (Ref1, Ref2) of official anchor points (OAP1-OAP6) outside the building (GB) for a reference floor of the building (GB);

Means (MG1, AV1, MG2, AV2) for reading in machine-readable markers (M1 - M3) attached to the defined location points (OPD1, OPD2) on the reference floor, whereby, based on the location points (OPD1, OPD2) the read-in markers (M1 - M3), a drift compensation of the geometry of the reference storey takes place, and a particularly digital volume model in the digital building model (BIM) for the rooms on the reference storey can be created in a suitable notation and stored in a storage medium ( DB) can be stored;

appropriately set up processing means (S) in order to use the digital volume model of the reference floor as a reference volume model when creating digital volume models dents for essentially identical to the reference floor

Floors of the building (GB) or another building.

8. Arrangement according to claim 7, wherein the storage medium (DB) is set up so that the reference volume model can be stored as a building information model (BIM).

9. Arrangement according to claim 7 or 8, wherein the storage medium (DB) is set up so that the digital volume models for the floors which are essentially identical to the reference floor can be stored as a building information model (BIM).