The more advanced the electronics, the more power they use. The more power they use, the hotter they get. The hotter they get, the more likely they’ll overheat. It doesn’t take a rocket scientist to understand what typically happens next: The electronics fry.
In the world of electronics, thermal control is always one of the limiting factors — particularly in space where there is no air to help cool down electronic components.
Called electrohydrodynamic (EHD)-based thermal control, the technology promises to make it easier and more efficient to remove heat from small spaces — a particular challenge for engineers building advanced space instruments and microprocessors that could fail if the heat they generate is not removed.
“Today, higher-power computer chips are available, but they generate too much heat,” said Didion, who is leading the technology-development effort also involving Matthew Showalter, associate branch chief of Goddard’s Advanced Manufacturing Branch, and Mario Martins of Edge Space Systems, an engineering company specializing in thermal systems in Glenelg, Md. “If I can carry away more heat, engineers will be able to use higher-power components. In other words, they will be able to do more things.”
The project, a joint activity between NASA Goddard and its partners, received support from the Goddard Internal Research and Development (IRAD) program, which funds the development of promising new technologies that could advance NASA’s scientific and exploration goals. It is being demonstrated in June on a Terrier-Improved Orion sounding rocket mission, which also is flying the Small Rocket/Spacecraft Technology (SMART) platform, a microsatellite also developed at Goddard. This new microsatellite measures about 16 inches in diameter and was specifically designed to give scientific users less expensive access to space.
The main objective of the EHD demonstration is showing that a prototype pump can withstand the extreme launch loads as the rocket lifts off and hurtles toward space. Should it survive the vibration, the technology will have achieved a major milestone in its development, Didion said. It will mean that it is at or near operational status, making it a viable technology for use on spaceflight instruments.
“Any electronic device that generates a lot of heat is going to benefit from this technology,” said Ted Swanson, assistant chief for technology for Goddard’s Mechanical Systems Division. This could include everything from sensors flown in space to those used in automobiles and aircraft.
No Moving Parts
The technology promises significant advantages over more traditional cooling techniques. Unlike current technologies used today by instrument and component developers, EHD does not rely on mechanical pumps and other moving parts. Instead, it uses electric fields to pump coolant through tiny ducts inside a thermal cold plate. From there, the waste heat is dumped onto a radiator and dispersed far from heat-sensitive circuitry that must operate within certain temperature ranges. “Its architecture, therefore, is relatively straightforward,” Didion said. Electrodes apply the voltage that pushes the coolant through the ducts.
“The advantages are many,” he added. “Without mechanical parts, the system is lighter and consumes less power, roughly half a watt. But perhaps more importantly, the system can be scaled to different sizes, from larger cold plates to microscale electronic components and lab-on-a-chip devices.”
Mahesh( MGIT ECE 3rd year)