SBIR-STTR Award

Lightweight, High-power Density, Self-protecting Superconducting Power Cables and Connectors for Electric Aircraft Applications
Award last edited on: 1/13/2022

Sponsored Program
SBIR
Awarding Agency
DOE
Total Award Amount
$996,403
Award Phase
2
Solicitation Topic Code
Q
Principal Investigator
Daniel (Danko) Van Der Laan

Company Information

Advanced Conductor Technologies LLC

3082 Sterling Circle Unit B
Boulder, CO 80301
   (888) 959-6405
   danko@advancedconductor.com
   www.advancedconductor.com
Location: Single
Congr. District: 02
County: Boulder

Phase I

Contract Number: DE-AR0001459
Start Date: 8/23/2021    Completed: 2/22/2022
Phase I year
2021
Phase I Amount
$231,108
The proposed program would develop 2-pole high-temperature superconducting dc power cables and connectors with a power rating of up to 50 MW that would enable twin-aisle aircraft with distributed electric propulsion in an effort to reduce carbon emissions of large passenger aircraft. The cables and connectors will contain dielectrics that are independent of the cryogenic medium used as coolant and would allow an operating voltage of 10 kV. The cables will have the ability to protect the power distribution network from overcurrents, in which the cables have intrinsic fault current limiting capabilities, reducing the complexity of the power distribution network, while improving its reliability. Advanced Conductor Technologies will develop coaxial 2-pole Conductor on Round Core (CORC®) dc cables and low-resistance connectors specifically for aircraft applications where size, weight and power density are key performance metrics. Dielectrics that allow the CORC® cables and connectors to operate at 10 kV will be developed by ACT in collaboration with the Center for Advanced Power Systems (CAPS) and Los Alamos National Laboratory (LANL). The superconducting cables and connectors will be incorporated in a sub-scale power distribution network that includes the cryogenic cooling infrastructure. The performance of the power cables, connectors and the sub-scale power distribution network will be tested using pressurized cryogenic helium gas at 40 – 60 K and in flowing liquid hydrogen at 20 K at NASA’s Glenn Research Center. A successful performance demonstration would be a game changer for the development of twin-aisle electric aircraft.

Phase II

Contract Number: DE-AR0001459
Start Date: 2/23/2022    Completed: 8/22/2024
Phase II year
2021
Phase II Amount
$765,295
The proposed program would develop 2-pole high-temperature superconducting dc power cables and connectors with a power rating of up to 50 MW that would enable twin-aisle aircraft with distributed electric propulsion in an effort to reduce carbon emissions of large passenger aircraft. The cables and connectors will contain dielectrics that are independent of the cryogenic medium used as coolant and would allow an operating voltage of 10 kV. The cables will have the ability to protect the power distribution network from overcurrents, in which the cables have intrinsic fault current limiting capabilities, reducing the complexity of the power distribution network, while improving its reliability.