AI-Assisted Design Coordination

Route every
service before
it clashes on site.

A senior building-services coordinator, running on every drawing you upload — reading levels, calculating ceiling zones, and routing ducts, trays, and pipework before anyone picks up a wrench.

SECTION A-A — CEILING VOID 3 CLASHES
U/S SLAB · RL 103.250 MECH DUCT 600Ø TRAY 300w HYDRAULIC — FALL 1:100 FIRE MAIN SPRINKLER RANGE CEILING · RL 102.600 FFL · RL 100.000 ZONE 650mm
hover the diagram — coordinated routing resolves clashes automatically
The Vision

Not a clash detector.
A coordinator.

  • 01Reads architectural, structural, and services drawings directly.
  • 02Understands slab levels, ceiling heights, FFL, U/S, beams, bulkheads, and risers.
  • 03Calculates the available ceiling space in every area of the building.
  • 04Weighs each service's priority and clearance requirements against the others.
  • 05Generates an optimised routing strategy for all services together.
  • 06Flags constructability issues before a single hanger goes in.
  • 07Produces coordinated drawings and reports an engineer would sign off on.
Worked example
Finished floor levelRL 100.000
Slab thickness250 mm
Underside of slabRL 103.250
CeilingRL 102.600
Usable services zone 650 mm
What It Reads

Every discipline,
one drawing set.

Uploaded architectural, structural, mechanical, hydraulic, fire, and electrical documents are parsed into a single spatial model — no discipline left to guesswork.

LAYER — ARCH

Architectural

  • Floor plans
  • Reflected ceiling plans
  • Sections
  • Room schedules
  • Ceiling types
  • Finished floor levels
LAYER — STRUC

Structural

  • Slab thickness
  • Beams & transfer beams
  • Post-tension cables
  • Openings & penetrations
  • Columns
LAYER — MECH

Mechanical

  • Duct sizes
  • Airflow
  • Equipment
  • Plant rooms
LAYER — HYD

Hydraulic

  • Pipe sizes
  • Falls
  • Pump locations
  • Drainage
LAYER — FIRE

Fire

  • Sprinkler mains
  • Hydrants
  • Booster assemblies
LAYER — ELEC

Electrical

  • Cable trays
  • Bus ducts
  • Switchboards
  • Lighting
Workflow

From drawing set
to coordinated model.

Upload architectural, structural, mechanical, hydraulic, fire, and electrical drawings — Revit, IFC, PDF, or DWG. The sequence below runs the same way on every project.

Read every document

Vision AI parses PDFs, DWGs, and BIM models across all six disciplines.

Build a unified 3D understanding

Geometry from every drawing set is merged into one spatial model of the building.

Identify available ceiling zones

Every void between structure and finished ceiling is measured, area by area.

Calculate spatial constraints

Beams, penetrations, bulkheads, and access requirements are mapped against each zone.

Apply coordination rules

Priority, clearance, and standards logic from the knowledge base is run against the model.

Optimise routing

An optimisation pass finds the routing path that fits every service into the available space.

Report clashes and resolutions

Remaining conflicts are surfaced with a recommended fix, not just a flagged coordinate.

Generate coordinated outputs

Drawings, schedules, and models are produced ready for engineer review.

The Brain

Five engines,
not one model.

A language model alone can't hold a building's geometry in its head. The technical work is done by dedicated engines working together — language is just how it explains itself.

Vision AI

Interprets PDFs, drawings, and plans across every discipline.

BIM / geometry engine

Understands 3D models and the spatial relationships between them.

Rules engine

Encodes construction standards and coordination priorities.

Optimisation algorithms

Finds the best routing through a limited ceiling space.

Language model

Explains decisions and answers questions in plain terms.

The language model is only one part — the geometry and optimisation engines do most of the technical work.

Knowledge Base

Rules an engineer
would already trust.

Expandable to match your own company standards, but grounded in how coordination is actually done on site.

Large ducts generally take priority
Gravity drainage must maintain minimum falls
Sprinklers require spacing and coverage
Cable trays need separation from other services
Access panels and maintenance clearances preserved
Structural elements need approval to modify
Coordination minimises offsets and fittings
Installation sequencing shapes practical routing
Outputs

What comes back
to the team.

01

Coordinated service layouts

02

Clash reports

03

Recommended reroutes

04

Installation sequencing

05

Bill of materials impacts

06

Penetration schedules

07

Ceiling congestion heat maps

08

3D coordinated models

09

Markups for engineer review

Staged Development

Built in four phases,
not one leap.

Each phase stands on its own and earns trust before the next one takes on more responsibility.

01

Foundation

  • Upload PDFs and IFC / Revit models
  • Extract levels and service info
  • Build a searchable project knowledge base
  • Answer questions about the project
02

Detection

  • Calculate available ceiling space
  • Detect clashes
  • Apply routing rules
  • Recommend improved layouts
03

Generation

  • Auto-generate coordinated routing
  • Optimise for constructability
  • Optimise for maintenance
  • Produce revised coordinated drawings
04

Integration

  • Integrate directly with BIM software
  • Learn from engineer feedback
  • Support real-time collaboration
  • Support live revisions
Get In Touch

Tell us about
your project.

Share a bit about your drawing set and where coordination is causing the most pain — we'll follow up directly.

Response time Within one business day
What to include Project type, drawing formats (Revit / IFC / PDF / DWG), and the discipline set involved
Sheet A-00 · Concept enquiry

Coordination that goes
beyond clash detection.

Less rework, better constructability, and drawings a site team can actually build from — starting with Phase 1.