Metal additive manufacturing enables lean, green heat exchanger

The University of Maryland’s Center for Environmental Energy Engineering (CEEE) sums up its quest to deliver innovative approaches to energy conversion in two words: lean and green.

CEEE is working with Oak Ridge National Laboratory to develop the next generation of miniaturized air-to-refrigerant heat exchanges for HVAC and refrigeration applications. For this project, funded by the US Department of Energy’s Building Technologies Office, only one type of manufacturing could satisfy CEEE’s lean and green mandates: additive manufacturing. They turned to 3D System’s Quickparts service, which offers direct metal printing (DMP).

Greater efficiency in less time

CEEE provides innovative solutions and technology transfer to meet industrial research and development challenges. Sponsors are leading industrial companies and government agencies that pool research funds to augment direct support from the University of Maryland.

Quickparts is a leading provider of unique, custom-designed parts, offering instant online quoting, expertise in 3D design and printing, and proven manufacturing services support.

CEEE and Quickparts teamed to increase the efficiency of a 1 kW heat exchanger by 20% while reducing weight and size. The manufacturing cycle for the heat exchanger was reduced from months to weeks.

Original heat exchanger design.
Original heat exchanger design.

Making it manufacturable

On a global scale, heat exchange is a multi-billion-dollar industry touching everything from consumer goods to automotive and aerospace engineering.

CEEE’s extensive experimental and theoretical research has led to automated design algorithms for creating unique shapes for tubes and fins used in heat exchangers. The goal is to reach an optimal air-side thermal resistance and minimize the size and weight of the heat exchangers. But, these innovative designs require new ways of manufacturing, according to Vikrant Aute, director of CEEE’s Modeling and Optimization Consortium.

Design algorithms create unique shapes for tubes and fins in heat exchangers. The goal is to reach an optimal air-side thermal resistance and minimize the size and weight of the heat. exchangers.
Design algorithms create unique shapes for tubes and fins in heat exchangers. The goal is to reach an optimal air-side thermal resistance and minimize the size and weight of the heat. exchangers.

“Most of these designs are simply not economically manufacturable today,” says Aute. “They are too complex technically with small feature sizes and extremely thin material thicknesses.”

That’s where the unique capabilities of direct metal printing  (additive manufacturing) come into play. With additive manufacturing, complexity is free — it costs no more to create a highly complex design than it does a more simplistic one.

3D Systems’ ProX DMP 320 system enabled CEEE to prototype its heat exchanger with non-conventional, variable shapes that are not possible to manufacture using traditional forming techniques such as extrusion or stamping.

“DMP [direct metal printing] allowed us to manufacture highly unusual tube shapes in the form of a hollow droplet to carry the refrigerant,” says Aute.

Quickparts provided input into the design of the heat exchanger to ensure that it could be manufactured efficiently.

Final design of the additively made heat exchanger.
Final design of the additively made heat exchanger.

“The ProX DMP 320 allows us to deliver open-channel diameters and feature sizes as small as 250 microns in a reliable and repetitive way,” says Jonathan Cornelus, business development manager at Quickparts. “High pressure and leak-tight exchanger walls can be built as thin as 200 micrometers, which is a true game-changer for heat-exchanger applications.”

Better design in one part

Working together, CEEE and Quickparts optimized the heat-exchanger design so it could be printed as a single part that requires minimal secondary finishing operations. Manufacturing can be completed in weeks instead of months, enabling CEEE to test designs much earlier and more often during the research program. The one-part design also helps ensure greater reliability.

Heat Exchangers original design - final designV2

“With conventional manufacturing technologies, assembly by brazing extremely thin tubes to a manifold is a painstaking operation with low reliability when it comes to leakages under high-pressure conditions,” says Aute. “With additive manufacturing, no assembly is required since the part is produced in one continuous operation, no matter how complex the parts or how delicate the features.”

Besides the ability to handle complex parts at no extra cost, the ProX DMP 320 offers other advantages that fit into CEEE’s lean and green scenario.

Preset build parameters, developed by 3D Systems based on the outcome of nearly half-a-million builds, provide predictable and repeatable print quality for almost any geometry.

A new architecture simplifies set-up and delivers the versatility to produce all types of part geometries in titanium, stainless steel or nickel super alloy. Titanium was chosen for the CEEE heat exchanger project, based on its lack of porosity and the ability to provide extremely thin, but very strong, walls.

Exchangeable manufacturing modules for the ProX DMP 320 system reduce downtime when moving among different part materials, and a controlled vacuum build chamber ensures that every part is printed with proven material properties, density and chemical purity. The small portion of non-printed material can be completely recycled, saving money and providing environmental benefits.

CEEE performed extensive testing on the new heat exchanger design, using infrared cameras to verify that heat was dispersed uniformly over the exchanger and that all the narrow, droplet-shaped exchanger channels were open and functioning fully. Results showed that the DMP-manufactured heat exchanger performed as expected.

Adding mean to lean and green

The unique capabilities of direct metal 3D printers such as the ProX line is rapidly turning additive manufacturing systems from experimental prototyping tools into mainstream production assets for manufacturers worldwide.

“We are witnessing new applications and massive improvements for existing projects in upper-end aerospace and industrial equipment markets, especially in cases where reduced space, low weight and high efficiency are critical concerns,” says Quickparts’ Cornelus.

“CEEE’s heat-exchanger application exemplifies the importance of additive manufacturing in the lean manufacturing space for creating low-volume, high-complexity metal components. These parts are now performing critical functions under challenging conditions such as continuous stress, high pressure, repeated use and extreme temperatures.”

3D Systems
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