Moog's Naval Systems Business Unit has developed a peak sine drive controller that can handle 15 times as much power as its predecessor and is about 500 cubic inches smaller. The new design dramatically increases the amount of available power without increasing controller volume by refining topologies and using new fluid technology.
Jason Weiss, engineering manager for the business unit, told us Moog has previously designed 10kW peak sine drive controllers with low structure-borne vibration noise levels. Building on top of that experience, the unit set out to develop a 150kW peak controller and examined the challenges of increasing the power of the drive topology.
A new peak sine drive controller from Moog can handle 15 times the amount of power
and is 500 cubic inches smaller than its predecessor.
(Source: Moog Inc.)
Weiss said four areas predominantly impact power density: losses, thermal conductivity, operating temperature, and package volume. To reduce the losses within the controller, a trade study on using silicone carbide (SiC) switching devices in a multilevel configuration was performed. SiC MOSFETs have proven to have lower conduction and switching losses and operate at higher temperatures than silicon MOSFETs and insulated gate bipolar transistors.
Increasing the output voltage to approximately double that of the baseline design helped decrease the output current and reduced filter losses. As a result, the design used a multilevel configuration versus a standard inverter, which would provide for a reduction in voltage stress on the desired switching devices. The overall controller was designed for a system efficiency of 95 percent.
Although we were able to increase our efficiency, we still had to manage 7.5kW of heat. Various cooling and heat management methods were investigated, including natural convection, forced air, liquid cooling, and heat pipes. We considered factors such as weight, heat transfer, conductivity, complexity, cost, and feasibility. The areas providing the most benefit for our application were the water cooling for managing external heat and dielectric fluid to handle the internal heat.
To obtain a better understanding of the dielectric fluid immersion along with the SiC devices, Moog developed a test unit that could house high-power resistors, inductors, the SiC devices, and the drive circuitry. Weiss said that the engineered dielectric fluid has slightly higher conductivity than air, but the main heat transfer method of the fluid is phase changing, or boiling from a liquid into a vapor.
When a liquid boils, it takes energy (called heat of vaporization) to change from a liquid to a gas. During this phase change, the temperature of the liquid remains constant. The second part of the two-phase cycle is condensing. All the heat absorbed by the vapor rises with the vapor and must be transferred to the condenser for the phase change from vapor to liquid again. The liquid cold plate removes the heat from the enclosure to an external heat exchanger. A test unit was developed to understand the effects of the dielectric fluid Novec.