COTS helps engineers optimize missile fin actuation system

Courtesy of Portescap

Precise missile fin control can be the difference between hitting or missing the target. Fin actuation depends on a motion solution with reliable, high dynamic control, in a power-dense package. A customizable off-the-shelf (COTS) strategy can help achieve this outcome, minimizing development time while meeting the essential operational criteria.

To achieve precision within meters of the missile’s expected impact point, precise fin control is fundamental. While the guidance system controls the trajectory, the performance of the motion solution, comprising the motor and feedback control, is crucial to achieve accurate and responsive missile fin position. The capability to actuate fins to the precise angle, rapidly reacting to continual feedback, is essential to achieve target precision.  

Missile fin actuation demands a motion control system that can generate sufficient torque to move the position against aerodynamic forces, including velocity up to several times the speed of sound. However, mass and physical volume are critical constraints, both in terms of the aircraft’s overall payload when considering air-launched missiles, as well as the flight performance characteristics of the missile itself. 

High dynamic control

Brushless DC motors, also known as BLDC, are the preferred design, and a primary reason is their inherent power density. The absence of brushes can be combined with a slotless design that enables greater concentration of windings, boosting torque for the form factor. Increasing to 4 motor poles, rather than 2, also maintains the same low mass and dimensions, but optimizes torque. As a result, motor designs like the Portescap 30ECT Ultra EC can increase power output of the system by 20% for the given envelope. The 30ECT90 can generate up to 225mNm maximum continuous torque, as well as the peak torque required for high dynamic operation; it can also sustain 2 seconds peak torque creating 2.4Nm. 

High dynamic performance is essential to enable virtual real time fin control to maintain precise trajectory from situational feedback. Contributing to rapid acceleration, low inertia is achieved through the slotless design thanks to its lighter rotor, improving the dynamic response. A slotless motor also reduces cogging torque, providing the smooth motion delivery essential to optimize control. The BLDC motor’s electronic commutation is also vital to this process, and the 30ECT Ultra EC motors integrate Hall sensors to provide rotor position feedback, as well as motor control including speed and torque. 

Reliability is crucial

Considering the imperative for precision, ensuring fin actuation reliability is equally critical. Highly robust motor construction is essential, providing resistance to shock and vibration. Constructed from stainless steel, the 30ECT motors feature laser welded front flanges for additional durability. The motors can also operate across a wide temperature range, from -55°C to 85°C. The motor design optimizes thermal behavior in repetitive cycles with high peak load, typical to the requirement for a fin’s frequent positional changes. 

While the BLDC’s characteristics minimize losses in friction while improving thermal regulation, the slotless attributes minimize eddy currents that also contribute to heat generation. Reducing eddy currents also minimizes electronic noise, where ensuring electromagnetic compatibility, alongside avionics and electronics devices, is imperative. Moreover, the slotless design decreases the prospect of concentrated magnetic flux densities that can generate noise interference. 

COTS strategy advantages

Considering the stakes of missile fin actuation, a bespoke motion control approach is an option. However, time is the major constraint in design from scratch, where tooling development alone might take more than a year. Instead, a customizable off-the-shelf (COTS) solution is a practical strategy that combines a tailored design with fast delivery.

An international defense manufacturer engaged Portescap to provide a missile fin control actuation system based on this approach. Portescap’s ability to customize a COTS solution to facilitate a quick prototype, combined with experience in aerospace and defense projects, were key drivers in selecting the solution partner.

The 30ECT brushless DC motor and an M-Sense encoder were integrated into the design to maintain the small envelope and increase power output. The robust motor design met the environmental demands of the application, and careful material selection allowed the motor components to extend the 20-year storage life requirement.

Flexible engineering options

Portescap’s engineering team can also offer customization, such as different coils to match speed and voltage requirements, as well as various shaft lengths and connectors. Along with a choice of gearbox, encoder and feedback control options, engineers can provide mechanical design integration, such as housings and flanges, to suit.

Missile fin actuation is a highly specialized pursuit, but by engaging in a COTS approach, aerospace and defense engineering teams can quickly achieve a high-performance, cost-effective, motion solution.