Latest revision as of 16:48, 28 April 2026

ISO-Plane™

Container Air Logistics

One container. One aircraft. One mission.

ISO-Plane™ is an open collaborative aerospace project developing a dedicated light cargo aircraft capable of transporting a single 20-foot ISO container with autonomous loading and unloading.

Designed around the container — not around conventional palletized cargo — ISO-Plane aims to offer a new operational standard for fast, infrastructure-light air logistics.

The aircraft concept targets: direct transport of one ISO container, autonomous cargo handling from ground or truck trailer, operation from regular landing fields, and multi-role mission capability.

www.iso-plane.com

Key Figures
Container	1 × 20-foot ISO container
Payload target	Up to 8 tons
Range target	Up to 6,000 km
Engines	2 × Pratt & Whitney PW150A
Crew	2 pilots
Development status	TRL3 in progress

Executive Overview

The ISO-Plane is a specialized cargo aircraft concept designed to solve a structural gap in air freight: transporting a standard ISO container without requiring a large military-class aircraft or heavy ground loading infrastructure.

Today, aircraft capable of carrying a full ISO container are generally large platforms requiring substantial logistics support. Smaller cargo aircraft are efficient for regional operations but are not built around ISO container geometry. ISO-Plane addresses this gap by placing the 20-foot container at the center of the aircraft architecture.

Container-first architecture

The cargo bay, ventral door, lifting system and fuselage diameter are designed around one 20-foot ISO container.

Autonomous handling

Loading and unloading can be performed from the ground or directly from a truck trailer using onboard mechanisms.

Multi-role platform

The same airframe can support logistics, humanitarian operations, firefighting, medical modules and special missions.

Product Positioning

The Market Gap

Large military aircraft can transport ISO containers, but they are expensive, heavy and infrastructure-intensive.
Smaller regional aircraft cannot accommodate a standard 20-foot ISO container as a native cargo unit.
Conventional air freight requires palletization, specialized loaders and additional ground operations.

The ISO-Plane Answer

Direct air transport of one standard 20-foot ISO container.
Autonomous loading and unloading without cranes or external loaders.
Operation from regular landing fields.
Two-pilot crew with automated cargo handling.
Mission flexibility through containerized modules.

ISO-Plane proposes a new paradigm: containerized air logistics with minimal ground infrastructure.

Mission Applications

Mission	Operational Value
Logistics Operations	Rapid movement of high-value, urgent or strategic containerized cargo to remote or constrained locations.
Humanitarian Aid / Relief Operations	Deployment of medical, shelter, water, energy or communications modules after disasters.
Aerial Firefighting	Potential water-bombing capability using a dedicated containerized water module.
Special Missions / Defense Operations	Tactical transport of modular systems, sensitive cargo or mobile support infrastructure.

Autonomous loading system
Internal cargo integration
Medical container mission configuration

Key Technical Characteristics

Parameter	Value
Container	1 × 20-foot ISO container, ISO 668 standard
Payload	Up to 8 tons
Estimated MTOW	Approximately 30 tons
Range	Up to 6,000 km, mission dependent
Engines	2 × Pratt & Whitney PW150A turboprop engines
Wing configuration	High wing
Architecture	Twin-boom configuration
Landing gear	Q400-derived, retracting into engine nacelles
Cargo bay	Pressurized cargo compartment
Cargo system	Ventral three-panel cargo door and robotic lifting arms
Crew	Two pilots

Cargo Handling System

The defining innovation of the ISO-Plane is its integrated autonomous container handling system.

Ventral Cargo Door

The aircraft features a three-panel ventral opening mechanism designed to provide direct access to the container from below the fuselage.

This system enables:

Ground-level loading and unloading.
Direct truck-to-aircraft transfer.
Compatibility with a pressurized cargo bay architecture.
Preservation of structural continuity through separated opening functions.

Robotic Lifting Arms

The container is handled by onboard mechanized systems:

Four robotic lifting arms.
ISO corner twist-lock interface.
Autonomous alignment and positioning logic.
Backup system using four electric winches.

Loading scenarios include:

Container positioned directly on the ground.
Container positioned on a truck trailer behind the aircraft.
Aircraft or truck alignment followed by automatic lifting, locking and securing.

1. Align

Aircraft and container are aligned using the selected ground scenario.

2. Open

Rear and ventral cargo doors open to release the container access volume.

3. Lock & Lift

Robotic arms connect to ISO corners and lift the container.

4. Secure

The container is positioned, locked and prepared for flight.

Aircraft Architecture

Engines

The selected powerplant is the Pratt & Whitney PW150A turboprop, chosen for its compatibility with the targeted aircraft class and its use on the Q400 platform.

Key advantages:

Proven turboprop architecture.
Power level compatible with an estimated 30-ton MTOW class.
Integration opportunity with Q400-derived systems.

Landing Gear

The main landing gear is derived from the Bombardier Q400.

Design principle: the main landing gear retracts into the nacelles below the high-mounted wings to maintain clearance with the cargo bay.

This configuration:

Preserves the ventral cargo opening.
Avoids interference with the container bay.
Reduces landing gear leg length compared with a lower fuselage installation.
Supports the high-wing cargo architecture.

Wing & Structure

The ISO-Plane architecture includes:

High-wing configuration for ground and container clearance.
Twin-boom layout.
Central wing box designed for structural continuity.
Pressurized cockpit and cargo compartment.
Fuselage diameter sized for ISO container integration.

Technology Review

Technology Block	Purpose	Status
20-foot container integration	Native cargo unit for the aircraft	Validated concept
Ventral three-panel cargo door	Ground-level access and container clearance	Selected architecture
Rear cargo door	Access and alignment support during loading	Under detailed refinement
Robotic arms	Container lifting, stabilization and positioning	Concept validated at TRL2
Twist-lock interface	ISO corner fixation and structural locking	Retained principle
PW150A engines	Twin-turboprop propulsion	Selected baseline
Q400-derived landing gear	Landing gear integration in nacelles	Selected baseline

Development Status

The ISO-Plane project is developed through a progressive technology readiness approach.

Phase	Period	Main Achievements
TRL0	2012–2014	Initial concept exploration and aircraft architecture studies.
TRL1	2015–2018	Preliminary architecture definition and early cargo loading concepts.
TRL2	2024–2025	Digital mock-up, validated architectural choices, functional analysis and cargo loading scenarios.
TRL3	2026 onward	Detailed engineering studies, structural calculations, CFD, FEA and subsystem validation.

TRL2 achievements include:

Validated aircraft configuration.
3D digital mock-up.
Functional analysis.
Market and economic study.
Cargo handling scenarios.
Preliminary carbon footprint estimation.

TRL3 focus areas include:

Detailed structural calculations.
Aerodynamic refinement.
Finite Element Analysis.
CFD studies.
Cargo door structural validation.
Detailed lifting mechanism design.
Industrial partnerships for engines, landing gear and onboard systems.

Collaborative Model

ISO-Plane is developed as an open collaborative aerospace initiative under the Lesser Open Bee License 1.3.

The project combines:

Academic engineering contributions.
Industrial expertise.
Open technical documentation.
Architecture-level collaboration.
Potential private industrial modules integrated around an open core.

Known contributors and collaboration environments include:

ESTACA.
ENSTA Paris.
Student engineering teams.
Aerospace professionals and technical coordinators.
Technoplane and Collaborative Bee ecosystem.

www.iso-plane.com

Market Positioning

The ISO-Plane targets premium and strategic segments where speed, autonomy and direct container compatibility create operational value.

Target Users

Logistics operators.
Humanitarian organizations.
Defense and civil protection agencies.
Firefighting operators.
Industrial operators in remote areas.
Governments and emergency response organizations.

Value Proposition

Faster deployment of containerized payloads.
Less dependence on airport cargo infrastructure.
Reduced handling complexity.
Standardized mission modules.
Flexible aircraft usage across multiple markets.

Preliminary market analysis has considered a production target around 12 aircraft per year over a 10-year horizon, with a conceptual unit price estimate around €130 million. These figures remain preliminary and must be refined during business plan development.

Environmental Considerations

Operational carbon footprint studies have been initiated during the concept phase.

Baseline assumptions considered:

Around 3,400 kg of fuel for a 2-hour mission.
Around 10–11 tons of CO₂ per mission.
Around 9,000–11,000 tons of CO₂ annually for approximately 900 flights per year.

Future development directions include:

Sustainable Aviation Fuel compatibility studies.
Structural weight optimization.
Eco-design principles.
Aerodynamic refinement.
Long-term hybridization studies.

Why ISO-Plane?

01

Direct container transport

A standard 20-foot ISO container becomes an airborne mission module.

02

Autonomous logistics

The aircraft carries its own loading and unloading capability.

03

Operational flexibility

One platform can serve logistics, relief, firefighting and special missions.

04

Collaborative innovation

Open architecture principles help accelerate development and partnerships.

Join the Project

ISO-Plane is an open collaborative aerospace initiative welcoming engineers, students, researchers and industry stakeholders.

Collaboration opportunities include:

Aerodynamic studies.
Structural sizing.
Cargo door mechanisms.
Robotic lifting systems.
Systems integration.
Market analysis and business model refinement.
Certification and industrialization studies.

For collaboration inquiries and technical documentation:

www.iso-plane.com

Programme note: ISO-Plane is presented here as a development programme and partnership opportunity. The aircraft is not presented as certified or commercially available for operational service at this stage.

ISO-Plane™ — Rethinking container air logistics.

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