Manufacturing Efficiency

Michigan State University’s proposed technology is a highly scalable heat exchanger suited for high-efficiency power generation systems that use supercritical CO2 as a working fluid and operate at high temperature and high pressure. It features a plate-type heat exchanger that enables lower cost powder-based manufacturing. The approach includes powder compaction and sintering (powder metallurgy) integrated with laser-directed energy deposition additive manufacturing.

Michigan Technological University will use advanced ceramic-based 3D printing technology to develop next-generation light, low-cost, ultra-compact, high-temperature, high-pressure (HTHP) heat exchangers. These will be able to operate at temperatures above 1100°C (2012°F) and at pressures above 80 bar (1160 psi). Current technologies cannot produce the high density, monolithic sintered silicon carbide (SSiC) material required for high temperature, high pressure recuperators.

UTRC will develop a high temperature, high strength, low cost glass-ceramic matrix composite heat exchanger capable of a long operational life in a range of harsh environments with temperatures and pressures as high as 1100°C (2012°F) and 250 bar (3626 psi). UTRC designed its Counterflow Honeycomb Heat Exchanger (CH-HX) configuration with an oxidation-resistant material developed initially for gas turbine applications. Its core feature is a joint-free, 3D-woven assembly of webbed tubes and cylindrical shapes to reduce stress and simplify manufacturing.

UCLA will develop an extreme-condition heat exchanger technology targeted to ultra-high efficiency hybrid aviation power cycles. The heat exchanger will operate at 50 kW (thermal) at supercritical CO2 pressures of 80 and 250 bar (1160 and 3626 psi) in hot and cold streams and at a hot-stream inlet temperature of 800°C (1472°F). A metallic superalloy capable of withstanding high temperature and pressure will be used to fabricate a shell-and-tube-based design supplemented with 3D-printed tube augmentations.

International Mezzo Technologies will design, manufacture, and test a compact, nickel-based superalloy supercritical carbon dioxide (sCO2) recuperator (a type of heat exchanger). The recuperator will incorporate laser-welded micro tubes and function at 800°C (1,472°F) and 275 bar (3,989 psi). Currently, the cost of recuperators for power systems operating in these conditions is prohibitive. Laser welding micro tubes offers a low-cost approach to fabricating heat exchangers, which could increase the economic competitiveness of sCO2 power cycles.

The Carnegie Mellon team will develop a modular radial heat exchanger that includes flow through pin arrays and counter-flow headers. The team will fabricate the heat exchanger via laser powder bed fusion additive manufacturing, with superalloys selected for high temperature and high pressure capability. Multiple approaches will be used to smooth the heat exchanger components’ internal passages to minimize pressure drop.

Vacuum Process engineering will develop a superalloy-based printed circuit heat exchanger for operation at temperatures exceeding 800°C (1472°F) and pressures above 80 bar (1160 psi). The team will build the heat exchanger applying a diffusion solid-state welding manufacturing technique, which uses stacked individual metal sheets with semi-circular channels formed from a chemical treatment process.

MIT will develop a high performance, compact, and durable ceramic heat exchanger. The multiscale porous high temperature heat exchanger will be capable of operation at temperatures over 1200°C (2192°F) and pressures above 80 bar (1160 psi). Porosity at the centimeter-scale will serve as channels for the flow of working fluids. A micrometer-scale porous core will be embedded into these channels. A ceramic co-extrusion process will create the channels and core using silicon carbide (SiC).

CompRex aims to transform heat exchange technology for high temperature (>800°C or 1472°F) and high pressure (80 bar or 1160 psi) applications through the use of advanced metal and ceramic composite material, development of a new simplified manufacturing approach, and optimization of heat exchanger design based on the new material and manufacturing process.

The GE-led team will develop a metallic-based, ultra-performance heat exchanger enabled by additive manufacturing technology and capable of operation at 900°C (1652°F) and 250 bar (3626 psi). The team will optimize heat transfer versus thermomechanical load using new micro-trifurcating core structures and manifold designs. The team will leverage a novel, high-temperature capable, crack-resistant nickel superalloy, designed specifically for additive manufacturing.