• +1-703-684-6777
  • news@evtol.news

CFJ-VTOL eCargo (concept design)

CFJ-VTOL eCargo (eVTOL) air cargo concept design aircraft


CFJ-VTOL eCargo (concept design)
Coflow Jet, LLC.
Coral Gables, Florida, USA

Founded by Dr. Gecheng Zha in Florida, USA, Coflow Jet, LLC is has developed a new airfoil technology for aircraft, wind turbines and ship airfoils that increase the efficiency of wings and airfoils. The company is also in the process of developing an electric general aviation conventional takeoff and landing (CTOL) aircraft , an electric vertical takeoff and landing (eVTOL) air tax for advanced air mobility (AAM) and an eVTOL air cargo aircraft.

Coflow airfoil diagram

Coflow airfoil diagram

To begin to explain this new technology, conventional wings on an aircraft are shaped specifically to make the air move faster on top of the wing than on the bottom of the wing. When the air moves faster on the top of a wing, the pressure of the air decreases (or there is low pressure) while you have a higher pressure under the wing which creates the force that lifts wings into the air.

Dr. Zha has invented a mechanical system to increase the speed of the air on top of a wing. He calls this active flow control using he own invention called coflow jet (CFJ) technology. Inside the wing is a micro-compressor that blows pressurized air over the top leading edge of the wing (through duct work) and then there is duct work at the top trailing edge of the wing that collects the air and feeds it back to the micro-compressor (in duct work inside the wing) which then starts the process over again.

The CoFlow AFC airfoil utilizes powerful, energy efficient wing-embedded micro-compressor actuators to inject pressurized air over the wing surface through a suction and injection system. To create the desired circulation and momentum, a small amount of air is suctioned at the wing’s trailing edge, energized, and injected tangentially at the leading edge. Wind tunnel tests and CFD simulations have demonstrated that CoFlow’s AFC airfoil creates a super-suction effect due to extremely low leading edge pressure, achieving an unprecedented stall angle of attack of 70 degrees or more, while typical airfoils reach maximum lift in the range of 15 to 18 degrees. -Quote from Yahoo! article.

Here are some of the benefits of Coflow Jet technology:

  • Increased mission efficiency
  • Decreased operating costs
  • Greater range
  • Heavier payloads
  • Better maneuverability
  • Improved high-altitude performance
  • Reduced drag
  • Efficient anti-icing system
  • Shorter takeoff and landing distance
  • Faster takeoff and climb
  • Slower landing speeds
  • Lower noise
  • Technology can be used in multiple industries

This technology is an emerging field of fluid dynamics, active flow control (AFC) in aircraft applications and is on-demand manipulation of airflow around aircraft structures. This system produces the control authority needed to enhance wing aerodynamic performance throughout the entire flight regime, including takeoff, climb, cruise, descent, landing and when maneuvering. CoFlow’s disruptive airfoil technology represents a generational breakthrough and will transform the aerodynamic capabilities of fixed wing aircraft and in other industrial applications.

CoFlow’s AFC airfoil technology was developed over a period of 15 years by Dr. Gecheng Zha, Professor and Director of Aerodynamics and CFD (Computatoinal Fluid Dynamics) Lab at the University of Miami’s Department of Mechanical and Aerospace Engineering. A NASA NIAC Fellow, ASME Fellow and AIAA Associate Fellow, Dr. Zha was recently recognized as one of the World's Top 2% of Scientists in Aerospace and Aeronautics for 2020 based on the standardized citation metrics organized by Stanford University. -Quote from Yahoo! article.

The Coflow Jet (CFJ) technology can be used on aircraft wings, airplane wings, eVTOL and hybrid-electric VTOL aircraft wings, wind turbines and used on vertical airfoils to help propel large ships. To explain how Coflow Jet (CFJ) technology helps in multiple industries, the company has three different websites listed below.

Coflow wing with mechanical controls

Coflow wing with mechanical controls

Coflow wing vortex flow

Coflow wing vortex flow

Coflow eVTOL, airfoil inside airflow with micro-compressor, deflected slipstream speed (from top then counter clockwise)

Coflow eVTOL, airfoil inside airflow with micro-compressor, deflected slipstream speed (from top then counter clockwise)

CFJ-VTOL eCargo (concept design) aircraft
The CFJ-VTOL eCargo is a heavy-lift eVTOL air cargo concept design aircraft that is flown by one or two pilots. The maximum payload weight of the aircraft is 3,000 lb (1,361 kg) and has a range of 300 miles (482 km). The aircraft has 10 propellers and 10 electric motors fixed on the leading edge of the tandem tilt-wings. For VTOL flight, wings tilt to the vertical position and for forward flight, the wings tilt to the horizontal position. The wings use coflow technology to increase the overall efficiency of the aircraft. The aircraft is powered only by batteries.

A micro-compressor and duct work is inside the airfoil and the entire Coflow Jet (CFJ) technology assembly pushes pressurized air near the top leading edge of the airfoil and at the same time pulls air near the top trailing edge of the airfoil. It is this technology that provides the wing more lift (this is also called super-lift). This makes the aircraft more efficient on takeoffs and landings, is quieter, reduces drag, reduces fuel consumption, increases cruise speed and increases the aircraft's range. When a heating coil is added inside the wing, it will warm the air and de-ice the wing.

The fuselage is carbon fiber composite which is used because of its high-strength and low weight needed in all aircraft superstructures. The windows are larger than conventional aircraft allowing forward, left and right views with a solid roof above the passenger compartment. The aircraft had fixed tricycle wheeled landing gear.

There has been no timeline mentioned by the company when full scale prototypes or production aircraft are expected.


  • Aircraft type: Heavy-lift eVTOL air cargo concept design aircraft
  • Piloting: 1 or 2 pilots
  • Capacity: Cargo
  • Range: 300 miles (482 km)M
  • Maximum payload weight: 3,000 lb (1,361 kg)
  • Propellers: 10 propellers (stationary forward propellers)
  • Electric motors: 10 electric motors
  • Power source: Batteries
  • Fuselage: Carbon fiber composite
  • Windows: Typical cockpit windows
  • Wings: Tandem tilt-wings (with coflow technology inside the wings)
  • Landing gear: Retractable tricycle wheeled landing gear
  • Safety features: Distributed Electric Propulsion (DEP), provides safety through redundancy for its passengers and/or cargo. DEP means having multiple propellers (or ducted fans) and motors on the aircraft so if one or more propellers (ducted fans) or motors fail, the other working propellers (or ducted fans) and motors can safely land the aircraft. There are also redundancies in the sub-systems of the aircraft. Can land conventionally if the VTOL systems are not working.

Related Aircraft:

Company Insights: