bim-coordination - SKILL.md Agent Skill

name: bim-coordination description: > BIM coordination and model-based field management for construction superintendents. Manage clash detection workflows, model-to-field verification, 4D scheduling integration, laser scanning and point cloud operations, drone surveys, digital twin closeout handoff, and LOD specification tracking. Track clash reports, model reviews, field verifications, scan records, drone flights, and coordination meetings through a structured data model. Integrates with morning-brief, daily-report, rfi-preparer, look-ahead-planner, closeout-commissioning, and drawing-control. Triggers: "BIM", "model", "clash", "clash detection", "Navisworks", "Revit", "coordination", "4D", "laser scan", "point cloud", "drone", "digital twin", "LOD", "BIM execution plan", "BxP", "model review". version: 1.0.0

BIM Coordination Skill

Overview

The bim-coordination skill provides Building Information Modeling coordination and management capabilities for construction superintendents and field managers. This is not a skill about creating BIM models -- it is about using BIM models and their outputs to build better, faster, and with fewer conflicts in the field.

The construction superintendent's relationship with BIM has fundamentally changed. You are no longer handed a stack of 2D drawings and expected to figure out how everything fits together in three dimensions. Instead, you have access to coordinated 3D models that show exactly how structural, mechanical, electrical, plumbing, and architectural elements relate to each other in space and time.

Critical distinction: As a superintendent, you do not model. You USE models and their outputs. Your role is to:

Verify that what is modeled matches what is built (and vice versa)
Participate in clash detection workflows and drive field resolution
Use 4D scheduling visualizations to plan and communicate sequencing
Coordinate laser scanning and drone surveys for as-built documentation
Ensure the digital twin handoff at closeout meets owner requirements

How BIM Changes the Super's Workflow

Traditional (2D Plan Sets):

Overlay multiple sheets mentally to find conflicts
Discover clashes during installation (expensive, schedule-killing)
Rely on RFIs to resolve spatial conflicts after they are found in the field
As-built documentation through redline markups on paper

BIM-Based Coordination:

Clashes identified digitally before construction begins
3D visualization of complex intersections available on tablet in the field
4D scheduling ties model elements to activities for visual sequencing
Laser scanning and drones provide precise as-built verification
Digital twin handoff gives the owner a living model for facility management

This skill provides:

BIM Execution Plan (BxP) superintendent responsibilities
Clash detection workflows from identification through field resolution
Model-to-field verification methods and tolerances
4D scheduling integration for phasing and logistics
Laser scanning and point cloud management
Drone survey planning and deliverable management
Digital twin and closeout handoff requirements
LOD specification guidance by discipline and phase
Structured data model for all BIM coordination activities
Integration with other ForemanOS skills

Key Principle: BIM coordination is not a design-phase activity that ends when construction starts. The model is a living document that must be continuously verified against field conditions, updated with as-built information, and handed off as a functional digital twin at project completion.

BIM Execution Plan (BxP) -- Superintendent Responsibilities

What a BxP Contains

The BIM Execution Plan (also called BxP or BEP) is the project-specific roadmap for how BIM will be used. It is typically produced by the BIM Manager or VDC Manager during preconstruction and covers:

Project BIM goals and uses -- what BIM will be used for (coordination, scheduling, estimating, facility management)
Model ownership matrix -- who creates and maintains each discipline model
Model development schedule -- when models are due at each phase
LOD requirements by element -- level of development expected at each milestone
Software and platform standards -- Revit version, Navisworks version, file naming, exchange formats
Coordination process -- meeting schedule, clash detection rules, resolution workflow
Quality control procedures -- model audit checklists, validation rules
Deliverable requirements -- what the owner receives at closeout
File sharing and CDE (Common Data Environment) -- where models live, access permissions, version control

Superintendent's BxP Responsibilities

The super does not write the BxP but is responsible for key field-related elements:

Field Verification Protocol
- When and how field conditions are checked against the model
- Who performs verification (super, layout crew, survey team)
- What tolerances trigger a discrepancy report
- How deviations are documented and communicated back to the modeling team
Reality Capture Coordination
- Scheduling laser scans and drone flights
- Providing safe access for scanning crews
- Reviewing scan deliverables for completeness
- Coordinating scan timing with construction activities (scan before cover-up)
As-Built Model Updates
- Documenting field changes that differ from the coordinated model
- Red-lining model discrepancies for the BIM team to incorporate
- Verifying as-built model accuracy before closeout submission
BIM Coordination Meeting Participation
- Attending weekly (or biweekly) BIM coordination meetings
- Reporting field conditions that affect model accuracy
- Providing construction sequence input for 4D scheduling
- Identifying upcoming work areas that need clash resolution priority

Model Access -- Viewer Software

The superintendent needs read access to models but does not need full modeling software. Common viewer platforms:

Platform	Type	Cost	Key Features
Navisworks Freedom	Desktop viewer	Free	View NWD files, basic navigation, saved viewpoints
Autodesk Docs / BIM 360	Cloud platform	Included with project license	Browser/mobile, markup, issues, model coordination
Procore BIM	Cloud platform	Included with Procore license	Browser/mobile, linked to Procore workflows
Trimble Connect	Cloud platform	Free tier available	Browser/mobile, field overlay, mixed reality
Dalux	Cloud/mobile	Subscription	AR field overlay, BIM viewer, quality management

Field tip: Download models for offline viewing before going to areas with poor connectivity. Autodesk Docs and Procore both support offline model caching on tablets.

Clash Detection Workflows

Types of Clashes

Clash detection identifies conflicts between building systems before they become costly field problems. There are three types:

1. Hard Clashes (Physical Intersection)

Two elements occupy the same physical space
Example: Ductwork passes through a structural beam
Example: Conduit runs through a plumbing pipe
These MUST be resolved before installation -- there is no field fix for two objects in the same space

2. Soft Clashes (Clearance Violation)

Two elements do not physically intersect but violate required clearances
Example: Ductwork is within 2" of a sprinkler head (needs 18" clearance for NFPA compliance)
Example: Electrical panel has insufficient working clearance (NEC 110.26 requires 36" minimum)
Example: Insulated pipe does not have enough space for insulation thickness
Soft clash tolerances are defined per system and per code requirement

3. 4D Clashes (Time/Space Conflicts)

Two activities require the same space at the same time based on the schedule
Example: MEP rough-in scheduled in the same area where concrete is being poured
Example: Crane swing radius conflicts with active work area during the same week
4D clashes require schedule adjustment, not model adjustment

Clash Detection Tools

Tool	Capability	Typical User
Navisworks Manage	Full clash detection with Clash Detective	BIM/VDC Manager
BIM 360 Model Coordination	Cloud-based automated clash detection	BIM/VDC Manager, PM
Solibri	Rule-based model checking and clash detection	BIM Manager
Navisworks Simulate	Limited clash detection	Project Engineer
Trimble Connect	Basic interference checking	Field team

Super's role: You typically do not run the clash detection software. Your role is to review clash reports, prioritize resolution based on construction sequence, drive field resolution, and verify that resolved clashes are actually resolved in the field.

Reading Clash Reports

A typical clash report from Navisworks Clash Detective contains:

Clash ID: Unique identifier (e.g., CLH-MEP-STR-0042)
Clash Type: Hard, soft (with tolerance), or 4D
Status: New, Active, Reviewed, Resolved, Approved
Elements Involved: Element 1 (discipline, type, size) vs. Element 2 (discipline, type, size)
Grid Location: Column grid intersection (e.g., between grids C-D / 3-4)
Level/Elevation: Floor and elevation of the clash
Distance: For hard clashes, penetration depth; for soft clashes, clearance shortfall
Viewpoint: Saved camera position showing the clash in the model
Date Found: When the clash was first detected
Assigned To: Trade or person responsible for resolution

Grouping and Filtering Clash Reports

Raw clash counts can be overwhelming (thousands of clashes in a complex project). Effective management requires:

Group by Zone/Area -- Focus on areas coming up in the schedule first
Group by Discipline Pair -- MEP/Structural, MEP/MEP, MEP/Architectural
Filter Duplicates -- Same elements clashing at multiple points count as one issue
Filter by Tolerance -- Ignore clashes below meaningful thresholds (e.g., <1/16" penetration)
Prioritize by Schedule -- Areas with work starting in the next 2-4 weeks get priority

Superintendent's Role in Field Resolution

When a clash cannot be resolved through model adjustment alone, the super drives field resolution:

RFI Generation -- When the clash reveals a design conflict, generate an RFI with the clash viewpoint attached
On-Site Resolution -- When trades can resolve a routing conflict in the field within tolerances, document the agreed-upon solution
Field Routing -- When the model shows the ideal path but field conditions require adjustment, direct the adjusted routing and document for as-built

Clash Resolution Meeting Format

Frequency: Weekly during active coordination phases, biweekly during less intensive periods

Agenda:

Review new clashes since last meeting (5 min)
Status update on previously assigned clashes (10 min)
Walk through highest-priority clashes by area (20 min)
- Display clash viewpoint in model
- Identify responsible trades
- Discuss resolution options
- Assign resolution owner and deadline
Review upcoming work areas needing pre-clash check (5 min)
RFI status for design-related clashes (5 min)
Action items and next meeting date (5 min)

Attendees: Superintendent, BIM/VDC Manager, MEP Coordinator, affected trade foremen, Project Engineer (for RFI tracking)

Common Clash Categories

MEP vs. Structural:

Ductwork through beams or columns
Piping through shear walls
Conduit through post-tension tendons
Hangers conflicting with structural connections
Resolution: Typically requires structural engineer review; may need beam penetration sleeves, routing changes, or supplemental framing

MEP vs. MEP:

Ductwork vs. piping (most common)
Conduit vs. piping
Cable tray vs. ductwork
Fire sprinkler vs. everything else
Resolution: Priority rules apply (gravity drain > pressure pipe > ductwork > conduit > cable tray); coordinate elevation stacking

MEP vs. Architectural:

Ductwork in ceiling plenum exceeding ceiling height
Piping conflicts with wall framing
Equipment clearances vs. room dimensions
Access panel locations vs. finish requirements
Resolution: May require ceiling height adjustment, soffit additions, room dimension changes, or equipment relocation

Clash Resolution Documentation

Every resolved clash must be documented with:

Clash ID and original clash report reference
Resolution Description -- what was changed (routing, elevation, size, elimination)
Resolution Type -- model change, field adjustment, design change (RFI), tolerance acceptance
Responsible Party -- who made the change
Verification -- confirmation that the resolution is reflected in the model or documented as field deviation
Date Resolved and Date Verified

Clash Status Tracking

Status	Definition
New	Clash detected, not yet reviewed
Active	Reviewed, assigned to a responsible party for resolution
Reviewed	Resolution proposed, awaiting approval
Resolved	Resolution implemented in the model or documented as field deviation
Approved	Resolution verified in the field and/or model -- closed

Model-to-Field Verification

Tablet/Phone Overlay

Modern BIM workflows allow superintendents to overlay the 3D model on the physical job site using augmented reality (AR):

Dalux BIM Viewer -- AR overlay on iOS/Android, point device at installed work to compare against model
Trimble Connect AR -- Mixed reality overlay with Trimble hardware or mobile device
OpenSpace -- 360-degree capture walks linked to model for progress verification
HoloBuilder -- Job walk capture with BIM overlay comparison

Setup requirements: Calibrated device, known reference points (survey control), current model version loaded, adequate lighting for camera-based AR.

Accuracy considerations: Mobile AR is useful for gross conflict identification (is the duct in the right bay?) but not for precision measurement. Use total station or laser scanning for tolerance verification.

Layout from BIM Coordinates

BIM models contain precise coordinate data that can be exported directly to layout equipment:

Total Station with BIM Export -- Export point coordinates from the model, import to total station, lay out points in the field
Robotic Total Station (RTS) -- One-person layout using BIM coordinates with automated prism tracking
Layout software -- Trimble Field Link, Topcon MAGNET, Leica iCON -- bridge between BIM and field layout hardware

Workflow:

BIM coordinator exports layout points from the model (DXF, CSV, or native format)
Survey/layout crew imports points to total station controller
Points are laid out in the field with paint, tacks, or laser marks
As-built points are captured and compared back to the model
Deviations outside tolerance are flagged for resolution

Verification Tolerances by Trade and Element Type

Trade/Element	Typical Tolerance	Reference
Structural steel columns	+/- 1/4" plan, +/- 3/8" elevation	AISC Code of Standard Practice
Cast-in-place concrete walls	+/- 1/4" plan location	ACI 117
Cast-in-place concrete slabs	+/- 3/4" elevation (FF/FL dependent)	ACI 117
MEP rough-in (horizontal)	+/- 1/2" from model location	Project-specific (check BxP)
MEP rough-in (elevation)	+/- 1/4" from model elevation	Project-specific (check BxP)
Fire sprinkler heads	+/- 1" from ceiling grid	NFPA 13 / reflected ceiling plan
Curtain wall anchors	+/- 1/8" plan, +/- 1/4" elevation	Manufacturer specs
Embedded items	+/- 1/4" horizontal, +/- 1/2" vertical	Project-specific
Electrical rough-in (boxes)	+/- 1/2" plan, +/- 1/4" elevation	NEC / project specs
Plumbing waste/vent	+/- 1/4" for slope verification	UPC / IPC (slope tolerance 1/8"/ft min)

Critical note: Always check the project BxP and specifications for project-specific tolerances. The values above are industry-typical but your project may have tighter or looser requirements.

Field Discrepancy Reporting

When field conditions deviate from the model beyond tolerance, document using a model-to-field deviation log:

Field	Description
Deviation ID	Unique identifier (e.g., DEV-2024-0015)
Date	Date deviation discovered
Location	Grid intersection, level, room/area
Element	What was measured (e.g., "12" supply duct at grid C-4, Level 3")
Modeled Value	What the model shows (position, elevation, size)
Field Value	What was measured in the field
Deviation	Difference (e.g., "6" south of modeled location")
Within Tolerance?	Yes/No based on applicable tolerance standard
Impact	Effect on other trades, schedule, function
Resolution	Action required (move element, update model, RFI, accept as-is)
Status	Open, In Progress, Resolved

As-Built Model Updating Workflow

Field Documentation -- Super documents as-built conditions (photos, measurements, redline sketches)
Deviation Log Entry -- Discrepancy logged with all required fields
BIM Team Notification -- Deviation log shared with BIM coordinator/modeler
Model Update -- BIM team updates model to reflect as-built conditions
Verification -- Super reviews updated model against field to confirm accuracy
Closeout Integration -- As-built model becomes the basis for digital twin handoff

Extended reference: Detailed examples, templates, scoring rubrics, and best practices are in references/skill-detail.md.