Build the Prototype

Build one complete house. Measure it. Sensor it. Publish every nail. A built, lived-in, measured house transforms the Foundation from a concept to a demonstrated technology.

Contents

Why the Prototype Matters

The single most important action for the Foundation is to build one complete house, measure it, sensor it, and publish every nail. A built, lived-in, measured house transforms the Foundation from a concept to a demonstrated technology.

The prototype is not a model. It is a real house, lived in by real people, measured continuously for at least 12 months. It must prove four things: structural adequacy, thermal performance, buildability by non-specialists, and livability.

What the Prototype Proves

  • Structural: Load-bearing capacity, racking resistance, long-term creep deflection
  • Thermal: Measured U-values vs. calculated, heating/cooling demand, humidity management
  • Buildability: Time-per-operation, tool requirements, skill level needed, error frequency
  • Livability: Comfort, durability, maintenance requirements, user satisfaction
  • Economic: Actual cost vs. estimated, labour hours, professional fees

Prototype Specification

The prototype will be Shell A — 37.5m² (7.5m × 5m), single storey, with the following configuration:

  • Walls: Single RCP (145mm) with blown rockwool insulation
  • Foundation: Earth screws (helical piles)
  • Roof: Mono-pitch, 400mm I-joists, OSB deck, metal standing seam
  • Windows: 3× aluminium-clad timber, double glazed
  • Door: 1× solid timber external, 1× glazed patio
  • Off-grid: 4kWp solar, 10kWh battery, solar hot water, composting toilet, rainwater harvesting
  • Interior: OSB walls, pine tar treated, engineered oak floor
  • Services: Mini-split AC backup, induction hob, small fridge, LED lighting

Site Requirements

  • Location: Within 30 minutes of Lagos, Algarve
  • Land: Flat or gently sloping, minimum 200m²
  • Access: Vehicle access for flatbed trailer delivery
  • Soil: Suitable for earth screws (tested before build)
  • Legal: Temporary structure permit or full planning permission
  • Water: Connection or borehole for testing rainwater system
  • Grid: Connection available for testing off-grid vs. grid comparison

Build Timeline

Month 1

Site acquisition + preparation

Secure land, test soil for earth screws, clear and level, establish base camp.

Month 2

Material procurement

Order all materials to Leroy Merlin Portimão, arrange cutting service, schedule delivery.

Month 3 — Day 1

Foundation + floor

Install earth screws, timber joists, OSB floor deck. Day 1 complete.

Day 2–3

Wall panel fabrication + erection

Fabricate RCP panels on-site, erect walls, install windows as walls go up.

Day 4–5

Roof + weatherproofing

Install I-joists, OSB deck, membrane, metal roof. Achieve weathertightness.

Day 6–7

Insulation + services

Blow insulation, install electrics, plumbing, solar, hot water, composting toilet.

Day 8–10

Interior finishing

Interior OSB, pine tar treatment, flooring, kitchen, bathroom fixtures.

Month 4–15

Monitoring + documentation

Continuous sensor logging, monthly photo documentation, seasonal performance review.

Documentation Protocol

Every operation is documented:

  • Photography: Before/during/after every build phase, every component arrival, every tool in use
  • Video: Time-lapse of full build, instructional videos of key operations
  • Receipts: Every purchase photographed, catalogued, cross-referenced to build phase
  • Labour log: Time per operation, number of people, skill level, errors, corrections
  • Engineer notes: Structural observations, deviations from protocol, on-site decisions
  • Daily log: Weather, progress, problems, solutions, morale

Sensor Network

The prototype will be instrumented with a continuous monitoring network:

  • Internal temperature: 4× sensors (corners, different heights)
  • External temperature: 2× sensors (north and south façades)
  • Humidity: 4× internal sensors + 1× external
  • Wall core temperature: 2× sensors (embedded in RCP panels)
  • Roof deck temperature: 1× sensor (under metal roof)
  • Floor temperature: 1× sensor (under floor deck)
  • Electrical: Solar generation, battery state, consumption logging
  • Water: Rainfall, tank level, consumption
  • Air quality: CO₂, VOCs (indoor)

All sensors feed a central data logger publishing to a public dashboard in real time.

Testing Protocol

Structural Tests

  • Wall panel loading: Incremental load to documented deflection, compare to calculation
  • Racking test: Lateral load on completed wall, measure displacement
  • Long-term deflection: Measure floor and roof deflection at 1, 3, 6, 12 months

Thermal Tests

  • U-value verification: Co-heating test or heat flux meter measurement
  • Seasonal performance: Heating/cooling degree days vs. energy consumption
  • Thermal comfort: PMV/PPD indices per ISO 7730

Prototype Budget

ItemCost (€)
Materials (RCP shell + off-grid)25,700
Site preparation + access2,000
Professional fees (engineer, surveyor)3,000
Sensor network + data logger1,500
Documentation (cameras, storage, editing)1,000
Contingency (15%)4,980
TOTAL€38,180

Build Team

The prototype build will use a workshop model — participants pay a modest fee (€500–€1,000) to learn the system by building it:

  • Core team: 2–3 people with construction experience (carpenter, engineer, coordinator)
  • Workshop participants: 6–10 people paying to learn (covers material costs)
  • Volunteers: Local community members contributing labour
  • Observers: University students, journalists, policymakers

This model simultaneously funds the build, educates future builders, and generates media content.