High-Efficiency Rear Wing Kit - ND Miata


1,699.95 1699.95 USD 1,699.95


Not Available For Sale

    This combination does not exist.


    Verus Engineering started the rear wing design with a clean slate approach, utilizing our own airfoil profile created using ANSYS' adjoint solver.  As a result, we were able to create a wing that is highly efficient while generating significant downforce appropriate for the typical track day goer and street enthusiast.  By utilizing a swan neck mounting style, we were able to keep efficiency up by feeding the wing clean airflow, unlike typical bottom mount rear wings.

    The low drag force produced by this wing is perfect for the ND chassis due to the limited horsepower it produces in stock form.  This means corner speeds will increase without a large hit to straight-line top speed or MPG on the street.

    Note: Does not with the RF model. Roof cannot retract with wing installed.


    • Rear Wing Element Assembly

    • Rear Wing Uprights, Machined Aluminum (2)

    • Rear Wing Trunk Mount, Machined Aluminum (2)

    • Hardware Kit, Includes All Parts Necessary for a Seamless Install









    Optimized Airfoil Using ANSYS Adjoint Solver

    Improved Efficiency (L/D)

    Reduced Drag

    Increased Downforce

    Bolts to OEM Trunk

    Capable of Generating and Withstanding 300+lbs of Downforce

    Properly Sized for Most off the Shelf Front Aero Solutions




    Carbon Fiber Rear Wing, with Carbon Nomex Infill For Strength

    Billet Aluminum Mounts and Uprights

    Recessed Mounting on Airfoil for Improved Aerodynamics

    Uprights are Knife Edged on Rear and Rounded on Front for Improved Aerodynamics

    Stainless Hardware Throughout




    The Verus Engineering High-Efficiency Rear Wing was specifically designed for the ND Miata enthusiast who wants more rear-end downforce for track days, while not decreasing gas mileage substantially or completely ruining straight-line top speeds on the track. The wing mounts were specifically placed in the strongest location on the trunk and then reinforced to help prevent trunk damage. The wing uprights were optimized using CFD and FEA to ensure the most efficient airflow in a straight line and yaw conditions while being strong enough to handle the loads from the wing.

    Our CFD data and our real-world experimental data match up quite well. The wing hit all the major goals we set forth to achieve first in our CFD simulations and then with our real-world testing. The strong correlation between CFD data and real-world testing validates both our CFD analysis approach and the wing’s performance.