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1. (WO2019050731) METHOD AND SYSTEM FOR CONVERTING 3-D SCAN DISPLAYS WITH OPTIONAL TELEMETRICS, TEMPORAL AND COMPONENT DATA INTO AN AUGMENTED OR VIRTUAL REALITY
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CLAIMS

1 . A method for integrating substantially realtime telemeteric data into a building information model ("BIM") presented as an augmented reality display or a virtual reality display to one or more users comprising:

obtaining one or more 3-D scans of a teiemetric monitored facility from the group of monitored facilities including an industrial plant facility, an industrial processing platform, a commercial site, a floating production storage and offloading vessel, and a maritime vessel;

spatially aligning a compatible BIM with said one or more 3-D scans for said monitored facility and generating virtual reality BIM data which substantially spatially matches said monitored facility, said compatible BIM having data representative of: (i) at least one teiemetric monitor associated with at least one process occurring in said monitored facility, and (ii) at least two static components associated with said at least one process on said monitored facility;

obtaining dynamic component data representative of said at least one telemeteric monitor and representative of at least one controlled variable in said at least one process,

obtaining static component data representative of said at least two static components; linking said dynamic component data and said static component data with said virtual reality BIM data;

displaying on said augmented reality display or said virtual reality display said virtual reality BIM data, said dynamic component data and said static component data, one or both of said dynamic component data and said static component data concurrently displayed with said virtual reality BIM data upon a user's command.

2. The method for integrating substantially realtime telemeteric data into a BIM as claimed in claim 1 including at least one of: (a) generating said compatible BIM from a library of BIM data objects and said at least two static components are included in said library of BIM data objects, (b) generating said compatible BIM from a library of BIM data objects and said at least two static components are included in said library of BI data objects wherein said dynamic component data represents a dynamic data object for one or both of said two static components included in said library of BIM data objects; (c) wherein said compatible BIM includes data objects from a piping and instrumentation diagram ("P&ID") for said monitored facility, said P&ID representing said static component data, said static component data including instrumentation component data and control component data, said P&ID further representing said dynamic component data, said dynamic component data including process flow data in said monitored facility, instrumentation status data in said monitored facility and control status data in said monitored facility, said control component data at least effecting said process flow data; (d) wherein said compatible BIM includes data objects from as-built plans of said monitored facility; and ( e) wherein a first static component of said at least two static components is a pipe used in said at least one process, said first static component being pipe static component data; said one or more 3-D scans of said monitored facility having scan data representative of an insulation over said pipe; said one or more 3-D scans of said monitored facility having further scan data representative of a flange on said pipe; obtaining thickness data of said flange based upon said further scan data; obtaining one or both of an estimated outside diameter and an estimated inside diameter of said pipe based upon the flange thickness data; in said virtual reality BIM data, using a pipe BIM object data to represent said pipe; updating said pipe static component data with said one or both of said estimated outside diameter and said estimated inside diameter of said pipe; linking said dynamic component data with said pipe static component data for said at least one process occurring in said monitored facility.

3. The method for integrating substantially realtime telemeteric data into a ΒΓΜ as claimed in claims 1 or 2 wherein said dynamic component data is one of a plurality of said dynamic component data tables, at least one dynamic component data table including key performance indicator data for said monitored facility.

4. The method for integrating substantially realtime telemeteric data into a ΒΓΜ as claimed in claims I, 2 or 3 wherein said dynamic component data represents a dynamic data object for one or both of said two static components; and including overlaying on said virtual reality BIM data an animated image of said dynamic component data.

5. The method for integrating substantially realtime telemeteric data into a BIM as claimed in claims 1, 2, 3 or 4 including overlaying on said virtual reality BIM data an animated image of said dynamic component data.

6. The method for integrating substantially realtime telemeteric data into a BIM as claimed in claims I, 2, 3, 4 or 5 including displaying a first 3-D scan of said one or more 3-D scans; measuring a virtual distance between at least two displayed points on said first 3-D scan to generate a virtual distance data representative of an actual distance and either (a) spatially aligning said compatible BIM with said first 3-D scan using said virtual distance data to generate virtual reality ΒΓΜ data, or (b) storing said virtual distance data in one or both of said dynamic component data and said static component data wherein said virtual distance data is associated with one or both of said two static components.

7. The method for integrating substantially realtime telemeteric data into a BIM as claimed in claims 1, 2, 3, 4, 5 or 6 including providing a mobile detector operable to sense a condition on said monitored facility and generate acquired data on a first of said two static components; providing a telecommunications network coupled to said mobile detector; and uploading said acquired data via said telecommunications network and importing the same as one or both of said dynamic component data and said static component data wherein the uploaded acquired data is associated with one or both of said two static components.

8. The method for integrating substantially realtime telemeteric data into a BIM as claimed in claims 1, 2, 3, 4, 5, 6 or 7 including (m) wherein said substantially realtime telemeteric data includes dynamic component data matching dynamic data representative of at least one process occurring in said monitored facility; (n) wherein said one or more 3-D scans of said monitored facility represented as as-is data; (o) spatially aligning said compatible BIM with said as-is data to generate virtual reality BIM data which substantially spatially matches said monitored facility; (p) said compatible BIM having, for each discrete static component data, a discrete static object link permitting a respective display of said discrete static component data when said static object link is activated in said compatible BIM; (q) said compatible BIM having, for said dynamic component data, a dynamic object link permitting display of said dynamic component data when said dynamic object link is activated in said compatible BIM, ( r) displaying said virtual reality BIM data concurrently with one or both said dynamic component data and said static component data upon a users command, and (s) displaying upon another user's command said as-is data with or without a concurrent display of said virtual reality BIM data; (t) thereby permitting views of (a') said as-is data; (b') said virtual reality BIM data; (c'j said discrete static component data, and (d') said dynamic component data for said one process in said monitored facility.

9. The method for integrating substantially realtime telemeteric data into a BIM as claimed in claims 1, 2, 3, 4, 5, 6 or 7 including:

utilizing a first online memory store for point cloud data representing said 3-D scan data of said telemetric monitored facility;

utilizing a second memory store for said compatible BIM for said monitored facility with a plurality of static component data tables including said at least two static components, each static component data table matching a respective static component in said compatible BIM and visually represented in said 3-D scan data, said compatible BIM further having a plurality of dynamic component data tables, each dynamic component data table matching a respective process in a plurality of processes occurring in said monitored facility including said at least one process;

said dynamic component data tables having respective process telemetric data associated with said respective process as a telemetric dynamic component data table;

said static component data tables and said dynamic component data tables having respective data object links associated with corresponding static and dynamic components represented in said 3-D scan data,

whereby, upon display of said virtual reality BIM data and a user activation of a visual representation of the corresponding data object link for said static or dynamic component, the respective data object link causes concurrent display of said corresponding static or dynamic component table, and

whereby, upon further display of said virtual reality BIM data and a further user activation of a further visual representation of said dynamic component associated with said telemetric dynamic component data table, the respective data object link causes concurrent display of said corresponding telemetric dynamic component table.

10. The method for integrating substantially realtime telemeteric data into a BIM as claimed in claim 9 wherein another dynamic component data table includes key performance indicator data for said monitored facility.

1 1 . A method for integrating temporal data into a building information model ("BIM") presented as an augmented reality display or a virtual reality display to one or more users comprising:

obtaining at least a first and a second temporal 3-D scan over corresponding first and second disparate time frames of a temporally monitored facility from the group of monitored facilities including an industrial plant facility, an industrial processing platform, a commercial site, a floating production storage and offloading vessel, a maritime vessel, and a heritage site;

spatially aligning a first compatible BIM with said first temporal 3-D scan for said monitored facility based upon at least a primary and a secondan,' static component in both said first temporal 3-D scan and said first compatible BIM;

generating a first virtual reality BIM data which substantially spatially matches said monitored facility at said first disparate time frame based upon a best fit algorithm with said primary and secondary static components;

said first compatible BIM having data representative of said primary and secondary static components and said monitored facility at said first disparate time frame;

spatially aligning a second compatible BIM with said second temporal 3-D scan and generating a second virtual reality BIM data which substantially spatially matches said monitored facility at said second disparate time frame and substantially spatially matches said first compatible said second compatible BIM having data representative of at least a tertiary static component associated with said monitored facility at said second disparate time frame;

generating dynamic component data based upon said primary, secondary and tertiary static component data, said dynamic component data being an estimation of a fully functional BIM for said monitored facility;

linking said dynamic component data and said primary, secondary and tertiary static component data with said second virtual reality BIM data;

displaying on said augmented reality display or said first and second virtual reality display said virtual reality BIM data, said dynamic component data and said static component data, one or both of said dynamic component data and said static component data concurrently displayed with said virtual reality BIM data upon a user's command.