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1. Large Format Composite Additive Manufacturing for Low-Head Hydropower

Author

Alex Roschli, Brian Post, Randal Mueller, Vito Gervasi, Phillip Chesser, Jesse Heineman, and Rebecca Brink

Subjects
3d printed dam, hydropower composite tooling, flow conveyance, 3d printed renewable energy, electric power generation, Industrial engineering. Management engineering, T55.4-60.8
Abstract

ABSTRACT: Hydropower with a small elevation change from inlet to outlet, known as “low-head” hydropower, is a relatively untapped resource for reliable green power generation. One major barrier to entry is the cost of the components needed to generate the power. Each installation site is unique, with various head levels, flow rates, and other unique site characteristics that drive up the cost of development and installation. As a result, custom-made components are necessary because the sites are intrinsically inefficient. However, customized parts are generally more expensive to manufacture than ready-made parts. Often times, the cost of custom-made components is so high that the low-head hydropower installation becomes non-viable. Additive manufacturing offers the ability to make custom components, ideal for one-off applications, at low costs that are well suited for the needs of low-head hydropower. Indirect additive manufacturing, such as making tools or dies rather than end use components, can also be used to make low-cost composite tooling as needed for these custom applications. This paper explores the use of additive manufacturing, both directly and indirectly, to produce the components of a turbine system for a low-head hydropower site. The parts were designed to form a unique modular system, which saves time for future designs and iterations. The system has operated for more than three years without failure at a test site in Wisconsin, USA. This work serves as a basis for future application of AM to low-head systems, in which the modular components can be customized for each unique hydropower installation.

Published
2023
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2. Distributed manufacturing: A case study in additive manufacturing face masks for the COVID-19 pandemic

Author

Alex Roschli, Peter Wang, Christopher Hershey, Brian Post, John Lindahl, and Lonnie Love

Subjects
COVID-19, Facial respirator, Pandemic, Face mask, N95, Silicone casting, Industrial engineering. Management engineering, T55.4-60.8
Abstract

At the onset of the COVID-19 (Coronavirus Disease 2019) pandemic, USA faced supply chain issues causing a nationwide shortage of N95 respirators and PAPR devices. Researchers at Oak Ridge National Laboratory's (ORNL) Manufacturing Demonstration Facility (MDF) were sent to work from home to help slow the spread of the pandemic, and during that time they were tasked with using their manufacturing expertise to research alternative methods of producing face masks. To rapidly iterate on face mask designs without access to a research or manufacturing facility, 3D (3-Dimensional) printing and silicone casting were used. Molds and components for the masks are modeled with computer-aided design (CAD), printed with common home desktop 3D printers, and test poured with skin-safe silicone rubber. The resultant masks are form fitting and comfortable to wear. To ease the shortage of N95 filter media, the masks are designed to use existing filter materials such as home HVAC (heating, ventilation, and air conditioning) filters. The masks can be sanitized, and the filter replaced to allow the same mask to be reused. The result is not equivalent to an N95 mask, and not meant to be a replacement, but is meant to be a stopgap mask that is still able to provide the wearer filtered protection. Filtration testing has not been performed because it is not the intention of the authors to make medical claims. This research is meant to demonstrate the rapid design, iteration, and manufacturing processes of a stopgap mask.

Published
2021
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3. Using Big Area Additive Manufacturing to directly manufacture a boat hull mould

Author

Brian K. Post, Phillip C. Chesser, Randall F. Lind, Alex Roschli, Lonnie J. Love, Katherine T. Gaul, Matthew Sallas, Fletcher Blue, and Stephen Wu

Subjects
large-scale additive manufacturing, 3d printing, boat hull mould, tooling, big area additive manufacturing, baam, Science, Manufactures, TS1-2301
Abstract

Big Area Additive Manufacturing (BAAM) is a large-scale, 3D printing technology developed by Oak Ridge National Laboratory's Manufacturing Demonstration Facility and Cincinnati, Inc. The ability to quickly and cost-effectively manufacture unique moulds and tools is currently one of the most significant applications of BAAM. This work details the application of a BAAM system to fabricate a 10.36 m (34 ft) catamaran boat hull mould. The goal of this project was to explore the feasibility of using BAAM to directly manufacture a mould without the need for thick coatings. The mould was printed in 12 individual sections over a five-day period. After printing, the critical surfaces of the mould were CNC-machined, the sections were assembled, and a final hull was manufactured using the mould. The success of this project illustrates the time and cost savings of BAAM in the fabrication of large moulds.

Published
2019
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6. Additive Manufacturing Design Guidelines for Wind Industry

Author

Amiee Jackson, Celeste Atkins, Abby Barnes, Vidya Kishore, Brian Post, Christopher Hershey, Michael Borish, Halil Tekinalp, Alex Roschli, Phillip Chesser, Tyler Smith, Pum Kim, Vlastimil Kunc, Lonnie Love, David Snowberg, and Scott Carron

Published
2022

7. Recent developments in filtration media and respirator technology in response to COVID-19

Author

Peter L. Wang, Yuepeng Zhang, Lonnie J. Love, M. Parans Paranthaman, Corson L. Cramer, Chris Zangmeister, Alex Roschli, Jeffrey J. Urban, and Merlin Theodore

Subjects
Manufacturing methods, business.product_category, Coronavirus disease 2019 (COVID-19), Mechanical Engineering, N95 respirators and filter, Supply chain, Stockpile, Economic shortage, Materials Engineering, Review Article, Reuse, Condensed Matter Physics, Manufacturing engineering, Macromolecular and Materials Chemistry, law.invention, law, General Materials Science, Filtration efficiency, Physical and Theoretical Chemistry, Respirator, business, Antiviral properties, Filtration, Applied Physics
Abstract

Abstract The COVID-19 pandemic triggered a surge in demand for N95 or equivalent respirators that the global supply chain was unable to satisfy. This shortage in critical equipment has inspired research that addresses the immediate problems and has accelerated the development of the next-generation filtration media and respirators. This article provides a brief review of the most recent work with regard to face respirators and filtration media. We discuss filtration efficiency of the widely utilized cloth masks. Next, the sterilization of and reuse of existing N95 respirators to extend the existing stockpile is discussed. To expand near-term supplies, optimization of current manufacturing methods, such as melt-blown processes and electrospinning, has been explored. Future manufacturing methods have been investigated to address long-term supply shortages. Novel materials with antiviral and sterilizable properties with the ability for multiple reuses have been developed and will contribute to the development of the next generation of longer lasting multi-use N95 respirators. Finally, additively manufactured respirators are reviewed, which enable a rapidly deployable source of reusable respirators that can use any filtration fabric. Graphic abstract

Published
2021

8. Relevant Additive Manufacturing Materials for Wind Industry

Author

Vidya Kishore, Tyler Smith, Pum Kim, Vlastimil Kunc, Christopher Hershey, Brian Post, Celeste Atkins, Amiee Jackson, Lonnie Love, Abby Barnes, Michael Borish, Halil Tekinalp, Alex Roschli, Phillip Chesser, David Snowberg, and Scott Carron

Published
2022

10. Rethinking production of machine tool bases: Polymer additive manufacturing and concrete

Author

Justin West, Emma Betters, Lonnie J. Love, Alex Roschli, David Nuttall, Tony L. Schmitz, John Lindahl, and Scott R. Smith

Subjects
business.product_category, Computer science, Base (geometry), Modal testing, Stiffness, Mechanical engineering, engineering.material, medicine.disease_cause, Industrial and Manufacturing Engineering, Machine tool, Mechanics of Materials, Mold, engineering, medicine, Cast iron, medicine.symptom, business, Reduced cost, Lead time
Abstract

Cast iron and steel weldments are the most common machine tool base elements. However, both construction methods have associated disadvantages for domestic machine tool manufacturers. This paper documents the investigation of an alternative method for machine tool base production using concrete to fill an additively manufactured polymer mold, where the motion components are attached to the concrete base after the initial concrete curing. Modal testing results for a three-axis, vertical spindle prototype indicate high damping and stiffness can be achieved using the concrete base construction. Advantages are reduced cost and lead time compared to traditional methods.

Published
2022

12. Real-Time Defect Correction in Large-Scale Polymer Additive Manufacturing via Thermal Imaging and Laser Profilometer

Author

Lonnie J. Love, Michael Borish, Brian K. Post, Phillip C. Chesser, and Alex Roschli

Subjects
0209 industrial biotechnology, Materials science, Scale (ratio), Mechanical engineering, Context (language use), 02 engineering and technology, Oak Ridge National Laboratory, Industrial and Manufacturing Engineering, Material flow, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, 0203 mechanical engineering, Artificial Intelligence, Control system, Thermal, Layer (electronics), Flip chip
Abstract

Defects can result in a failed part and are costly in terms of time and material. This cost is even greater in the context of large-scale additive manufacturing where the objects can be very large. As a result, a great deal of research has focused on defect identification and mitigation. To address defects during object construction, researchers at Oak Ridge National Laboratory’s Manufacturing Demonstration Facility investigated an in-situ control system comprised of two sensors: a thermal camera and laser profilometer. This control system adjusted material flow and build speed to mitigate three types of defects: low layer times, underfill, and overfill. Several test objects were constructed. The control system was found to adjust build parameters to handle low layer times of approximately 15 seconds and height deviations from -100% underfill (the absence of a layer) to 50% overfill. Within two layers, height deviations could be returned to within 10% of the expected layer height. Further, preliminary results suggest the system can compensate for uneven build surfaces.

Published
2020

15. Extrusion control for high quality printing on Big Area Additive Manufacturing (BAAM) systems

Author

Alex Roschli, Charles L. Carnal, Michael Borish, Lonnie J. Love, Brian K. Post, Phillip C. Chesser, and Randall F. Lind

Subjects
0209 industrial biotechnology, Materials science, business.industry, Scale (chemistry), media_common.quotation_subject, Control (management), Plastics extrusion, Biomedical Engineering, Feed forward, Process (computing), 02 engineering and technology, 021001 nanoscience & nanotechnology, Industrial and Manufacturing Engineering, 020901 industrial engineering & automation, General Materials Science, Extrusion, Quality (business), 0210 nano-technology, Process engineering, business, Engineering (miscellaneous), media_common
Abstract

Big Area Additive Manufacturing (BAAM) is a large format additive manufacturing (AM) process. The size scale has enabled many new applications for AM. However, at this scale, lack of high print resolution and extruder flowrate control lead to potentially significant geometric deviations in the printed part. This paper examines strategies to improve geometric quality in BAAM parts. Multi-resolution printing, extrusion diversion, and feedforward extruder control are examined herein. These methods were all found to be effective in mitigating phenomena detrimental to geometric part quality on the BAAM process.

Published
2019

16. In-Situ Thermal Imaging for Single Layer Build Time Alteration in Large-Scale Polymer Additive Manufacturing

Author

Nikolaos Tsiamis, Alex Roschli, Phillip C. Chesser, Brian K. Post, Michael Borish, Lonnie J. Love, Matthew Sallas, and Katherine T. Gaul

Subjects
chemistry.chemical_classification, 0209 industrial biotechnology, Computer science, Scale (chemistry), Mechanical engineering, 02 engineering and technology, Polymer, Oak Ridge National Laboratory, Object (computer science), Industrial and Manufacturing Engineering, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, 0203 mechanical engineering, chemistry, Artificial Intelligence, Control system, Thermal, Layer (object-oriented design), Single layer
Abstract

Ideally, objects are constructed as quickly as possible; however, short build times for a layer can present an issue. Short layer build times do not provide enough time for the material to cool sufficiently. As a result, an object cannot support its own weight nor deal with overhanging features. Additionally, the generation of support structures may be impractical either due to geometry or, in the case of large-scale polymer additive manufacturing, due to being difficult to remove. To address these issues, researchers at Oak Ridge National Laboratory’s Manufacturing Demonstration Facility investigated the use of a thermal camera mounted to a gantry to collect data on an object under construction. This data provided feedback for an in-situ control system to adjust layer build times. Adjustments were made in the form of additional waiting to allow the material to cool to specific thermal thresholds. This additional cooling time allowed the construction of objects with low layer build times or overhanging features that would have otherwise failed.

Published
2019

17. Designing for Big Area Additive Manufacturing

Author

Phillip C. Chesser, Fletcher Blue, Lonnie J. Love, Katherine T. Gaul, Alex M. Boulger, Alex Roschli, Brian K. Post, and Michael Borish

Subjects
0209 industrial biotechnology, Materials science, business.industry, Biomedical Engineering, 3D printing, 02 engineering and technology, Oak Ridge National Laboratory, 021001 nanoscience & nanotechnology, Slicing, Industrial and Manufacturing Engineering, Manufacturing engineering, 020901 industrial engineering & automation, Software, Work (electrical), Manufacturing, General Materials Science, 0210 nano-technology, Engineering design process, business, Engineering (miscellaneous), Host (network)
Abstract

Additive manufacturing (AM), more commonly referred to as 3D printing, is revolutionizing the manufacturing industry. With any new technology comes new rules and guidelines for the optimal use of said technology. Big Area Additive Manufacturing (BAAM), developed by Cincinnati Incorporated and Oak Ridge National Laboratory’s Manufacturing Demonstration Facility, requires a host of new design parameters compared to small-scale 3D printing to create large-scale parts. However, BAAM also creates new possibilities in material testing and various applications in the manufacturing industry. Most of the design constraints of small-scale polymer 3D printers still apply to BAAM. Beyond those constraints, new rules and limitations exist because BAAM’s large-scale system significantly changes the thermal properties associated with small-scale AM. This work details both physical and software-related design considerations for additive manufacturing. After reading this guide, one will have a better understanding of slicing software’s capabilities and limitations, different physical characteristics of design and how to apply them appropriately for AM, and how to take the inherent nature of AM into consideration during the design process.

Published
2019

18. Empower Wall: Active insulation system leveraging additive manufacturing and model predictive control

Author

Celeste Atkins, Diana Hun, Piljae Im, Brian Post, Bob Slattery, Emishaw Iffa, Borui Cui, Jin Dong, Abigail Barnes, Joshua Vaughan, Alex Roschli, Mikael Salonvaara, Som Shrestha, Sungkyun Jung, Phillip Chesser, Jesse Heineman, Peter L. Wang, Amiee Jackson, and Melissa Voss Lapsa

Subjects
Fuel Technology, Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology
Published
2022

19. Assessment of Commercial Composite Power Pole Performance

Author

Lonnie Love, Brian Post, Halil Tekinalp, Peter Wang, Celeste Atkins, Alex Roschli, Xianhui Zhao, and Mitch Rencheck

Subjects
Computer science, Composite number, Automotive engineering, Power (physics)
Published
2021

20. ORNL Slicer 2 v0.93 BETA

Author

Alex Roschli, Canhai Lai, and Michael Borish

Subjects
Chemistry, Radiochemistry, Beta (finance)
Published
2021

21. Additively Manufactured Power Poles

Author

Brian K. Post, Alex Roschli, Peter L. Wang, Celeste Atkins, and Halil Tekinalp

Subjects
business.industry, Computer science, Electrical engineering, business, Power (physics)
Published
2021

23. Construction-Scale Concrete Additive Manufacturing and its Application in Infrastructure Energy Storage

Author

Jesse Heineman, Joshua E. Vaughan, Brian K. Post, Phillip C. Chesser, Peter L. Wang, Alex Roschli, Celeste Atkins, Melissa Voss Lapsa, Diana E. Hun, Emma Betters, Amy Loy, and Alex M. Boulger

Subjects
Scale (ratio), business.industry, Heat transfer, Environmental science, Process engineering, business, Energy storage
Abstract

Construction is filled with labor intensive, hazardous, and often wasteful processes. It is also an enormous industry, so improvements in efficiency could have a tremendous economic impact. Construction-scale additive manufacturing is one path toward achieving those improvements. In this paper, a construction-scale additive manufacturing system, called Sky-BAAM, is presented. In addition to possibly leading to more energy-efficient construction practices, leveraging additive manufacturing in construction opens the solution space to more energy efficient building design. One such design, the EMPOWER wall, is also presented in this paper. The exterior of the wall is shaped to maximize heat transfer, while acting as form work for an internal energy-storage system. This allows energy to be stored in the wall during off-peak times and retrieved during peak periods.

Published
2020

25. Defect Identification and Mitigation Via Visual Inspection in Large-Scale Additive Manufacturing

Author

Brian K. Post, Katherine T. Gaul, Alex Roschli, Michael Borish, Phillip C. Chesser, and Lonnie J. Love

Subjects
Engineering drawing, Computer science, media_common.quotation_subject, Scale (chemistry), 0211 other engineering and technologies, General Engineering, 02 engineering and technology, Oak Ridge National Laboratory, 021001 nanoscience & nanotechnology, Object (computer science), Visual inspection, Identification (information), Control system, General Materials Science, Quality (business), 0210 nano-technology, Representation (mathematics), 021102 mining & metallurgy, media_common
Abstract

Defect identification and mitigation is an important avenue of research to improve the overall quality of objects created using additive manufacturing (AM) technologies. Identifying and mitigating defects takes on additional importance in large-scale, industrial AM. In large-scale AM, defects that result in failed prints are extremely costly in terms of time spent and material used. To address these issues, researchers at Oak Ridge National Laboratory’s Manufacturing Demonstration Facility investigated the use of a laser profilometer and thermal camera to collect data concerning an object as it was constructed. These data provided feedback for an in situ control system to adjust object construction. Adjustments were made in the form of automated height control. This paper presents results for both a polymer- and metal-based system. Object construction for both systems was improved significantly, and the resulting objects were more geometrically identical to the ideal 3D representation.

Published
2018

26. Using Big Area Additive Manufacturing to directly manufacture a boat hull mould

Author

Brian K. Post, Randall F. Lind, Alex Roschli, Lonnie J. Love, Stephen Wu, Katherine T. Gaul, Phillip C. Chesser, Matthew Sallas, and Fletcher Blue

Subjects
0209 industrial biotechnology, Engineering, business.industry, 3D printing, 02 engineering and technology, Oak Ridge National Laboratory, 021001 nanoscience & nanotechnology, Computer Graphics and Computer-Aided Design, Industrial and Manufacturing Engineering, 020901 industrial engineering & automation, Modeling and Simulation, Hull, Signal Processing, 0210 nano-technology, business, Marine engineering
Abstract

Big Area Additive Manufacturing (BAAM) is a large-scale, 3D printing technology developed by Oak Ridge National Laboratory's Manufacturing Demonstration Facility and Cincinnati, Inc. The ability to...

Published
2018

28. Large-scale additive manufacturing of self-heating molds

Author

Jerry Jackson, Ahmed Arabi Hassen, Kazi Md Masum Billah, Jesse Heineman, Alex Roschli, Vipin Kumar, Zach Skelton, Brian K. Post, Seokpum Kim, Gregory Haye, Vlastimil Kunc, and Parithosh Mhatre

Subjects
business.product_category, Materials science, Heating element, Glass fiber, Composite number, Biomedical Engineering, Fiber-reinforced composite, Industrial and Manufacturing Engineering, Flexural strength, Ultimate tensile strength, Die (manufacturing), General Materials Science, Extrusion, Composite material, business, Engineering (miscellaneous)
Abstract

Large-scale material extrusion additive manufacturing technology is becoming the new mainstream technology for scaled-up composite mold and die applications. This paradigm shift in composite processing technology is primarily driven by out-of-autoclave tooling applications, in which fiber reinforced composite molds with scaled-up sizes and embedded heating elements are attractive. The present research describes the design, manufacturing, and testing of self-heating composite molds fabricated via a large-scale pellet extrusion 3D printing machine with an integrated wire co-extrusion tool. Polycarbonate (PC) composites reinforced with carbon fiber (PC/CF; 20 wt.%) and glass fiber (PC/GF; 20 wt.%) were used to fabricate mold parts. Joule heating thermal test results showed that uniform temperatures (~100 °C) were achieved for both PC/CF and PC/GF mold surfaces, using a custom-made feedback control power supply and infrared thermography. Mechanical characterizations, including tensile and flexural testing were performed on the wire-embedded and un-wired PC/CF and PC/GF base specimens to investigate the impact of the fiber reinforcement as well as the embedded wires. In the direction of extrusion, the ultimate tensile stress of PC/CF was 105 MPa, and that of PC/GF was 73 MPa, while the neat PC value was 64 MPa. Inner-bead voids and interfacial gaps were observed and characterized via optical and scanning electron microscopy. The embedded wires and inner bead impacted the mechanical properties of the composites. However, the stiffness of the wire-embedded mold was still satisfactory, proving that the technology can be used to fabricate additively manufactured out-of-oven/autoclave molds.

Published
2021

29. Distributed manufacturing: A case study in additive manufacturing face masks for the COVID-19 pandemic

Author

Lonnie J. Love, Alex Roschli, Peter L. Wang, John Lindahl, Christopher Hershey, and Brian K. Post

Subjects
business.product_category, Pandemic, business.industry, Computer science, Industrial engineering. Management engineering, Supply chain, N95, Facial respirator, COVID-19, Oak Ridge National Laboratory, T55.4-60.8, PAPR, Manufacturing engineering, Article, Face masks, Face mask, Filter (video), Air conditioning, HVAC, Silicone casting, Respirator, business, Distributed manufacturing
Abstract

At the onset of the COVID-19 (Coronavirus Disease 2019) pandemic, USA faced supply chain issues causing a nationwide shortage of N95 respirators and PAPR devices. Researchers at Oak Ridge National Laboratory's (ORNL) Manufacturing Demonstration Facility (MDF) were sent to work from home to help slow the spread of the pandemic, and during that time they were tasked with using their manufacturing expertise to research alternative methods of producing face masks. To rapidly iterate on face mask designs without access to a research or manufacturing facility, 3D (3-Dimensional) printing and silicone casting were used. Molds and components for the masks are modeled with computer-aided design (CAD), printed with common home desktop 3D printers, and test poured with skin-safe silicone rubber. The resultant masks are form fitting and comfortable to wear. To ease the shortage of N95 filter media, the masks are designed to use existing filter materials such as home HVAC (heating, ventilation, and air conditioning) filters. The masks can be sanitized, and the filter replaced to allow the same mask to be reused. The result is not equivalent to an N95 mask, and not meant to be a replacement, but is meant to be a stopgap mask that is still able to provide the wearer filtered protection. Filtration testing has not been performed because it is not the intention of the authors to make medical claims. This research is meant to demonstrate the rapid design, iteration, and manufacturing processes of a stopgap mask.

Published
2021

32. On-Site Manufacture of Large Cement Structures

Author

Jesse Heineman, Brian K. Post, Alex Roschli, Alex M. Boulger, Celeste Atkins, Randall F. Lind, Phillip C. Chesser, and Peter D. Lloyd

Subjects
Cement, Materials science, Metallurgy
Published
2019

34. Additive Manufacturing of Polyurethane Foam Mold Tooling

Author

Phillip C. Chesser, Breanna J. Rhyne, Brian K. Post, Alex Roschli, Celeste Atkins, Matthew Sallas, and Nikolaos Tsiamis

Subjects
chemistry.chemical_compound, Materials science, chemistry, Mold, medicine, Composite material, medicine.disease_cause, Polyurethane
Published
2019

35. Evaluation of Strangpresse Extruder on ORNL BAAM

Author

Peter D. Lloyd, Alex M. Boulger, Brian K. Post, Lonnie J. Love, Alex Roschli, Phillip C. Chesser, and Bradley S. Richardson

Subjects
Materials science, Waste management, Plastics extrusion
Published
2019

39. Pellet to Part Manufacturing System for CNCs

Author

Peter D. Lloyd, Katherine T. Gaul, Yashwanth K. Bandari, Alex Roschli, Lonnie J. Love, Phillip C. Chesser, Jason Jones, and Brian K. Post

Subjects
Materials science, Metallurgy, Pellet, Manufacturing systems
Published
2018

40. Gates Precast Concrete User Project Phase 1

Author

Lonnie J. Love, Alex Roschli, Brian K. Post, and Phillip C. Chesser

Subjects
business.industry, Phase (matter), Precast concrete, Structural engineering, business
Published
2017

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