Additive manufacturing team hi-res stock photography and images

3D-printed unexploded ordnances made for training purposes sit on a table at the Hercules Innovation Lab at Ramstein Air Base, Germany, July 8, 2022. Members of the Additive Manufacturing Team at Ramstein designed 3D-printed UXOs for Explosive Ordnance Disposal technicians to use as training aids. Stock Photo

RM2MCRW6H–3D-printed unexploded ordnances made for training purposes sit on a table at the Hercules Innovation Lab at Ramstein Air Base, Germany, July 8, 2022. Members of the Additive Manufacturing Team at Ramstein designed 3D-printed UXOs for Explosive Ordnance Disposal technicians to use as training aids.

(230511) -- BEIJING, May 11, 2023 (Xinhua) -- This photo taken on April 24, 2023 shows the lunar samples received by the Beijing Institute of Technology. The Beijing Institute of Technology (BIT) recently received 500 mg of the lunar samples brought back by the Chang'e-5 mission. The research team with BIT will study the material characteristics of these samples and also related additive manufacturing technology, with the building of a future lunar research station in mind.TO GO WITH 'Across China: Chinese scientists to explore lunar construction materials, technology' (Xinhua/Zhao Xu) Stock Photo

RM2R114FB–(230511) -- BEIJING, May 11, 2023 (Xinhua) -- This photo taken on April 24, 2023 shows the lunar samples received by the Beijing Institute of Technology. The Beijing Institute of Technology (BIT) recently received 500 mg of the lunar samples brought back by the Chang'e-5 mission. The research team with BIT will study the material characteristics of these samples and also related additive manufacturing technology, with the building of a future lunar research station in mind.TO GO WITH 'Across China: Chinese scientists to explore lunar construction materials, technology' (Xinhua/Zhao Xu)

U.S. Air Force Airman 1st Class Kevin Garza, 86th Maintenance Squadron aircraft metals technology journeyman, measures tubing for a portable air conditioner at Ramstein Air Base, Germany, July 18, 2022. The Additive Manufacturing Team at Ramstein designed a 3D-printed replacement to hold tubing to an air conditioner and allow it to function properly again. Stock Photo

RM2NH5Y5N–U.S. Air Force Airman 1st Class Kevin Garza, 86th Maintenance Squadron aircraft metals technology journeyman, measures tubing for a portable air conditioner at Ramstein Air Base, Germany, July 18, 2022. The Additive Manufacturing Team at Ramstein designed a 3D-printed replacement to hold tubing to an air conditioner and allow it to function properly again.

230511 -- BEIJING, May 11, 2023 -- This photo taken on April 24, 2023 shows the lunar samples received by the Beijing Institute of Technology. The Beijing Institute of Technology BIT recently received 500 mg of the lunar samples brought back by the Chang e-5 mission. The research team with BIT will study the material characteristics of these samples and also related additive manufacturing technology, with the building of a future lunar research station in mind. TO GO WITH Across China: Chinese scientists to explore lunar construction materials, technology CHINA-BEIJING-BIT-LUNAR SAMPLECN Zhao Stock Photo

RM2RRR76J–230511 -- BEIJING, May 11, 2023 -- This photo taken on April 24, 2023 shows the lunar samples received by the Beijing Institute of Technology. The Beijing Institute of Technology BIT recently received 500 mg of the lunar samples brought back by the Chang e-5 mission. The research team with BIT will study the material characteristics of these samples and also related additive manufacturing technology, with the building of a future lunar research station in mind. TO GO WITH Across China: Chinese scientists to explore lunar construction materials, technology CHINA-BEIJING-BIT-LUNAR SAMPLECN Zhao

U.S. Air Force Tech. Sgt. Aaron Barnes, 86th Maintenance Squadron aircraft metals technology craftsman, previews a file to 3D print at Ramstein Air Base, Germany, July 21, 2022. Barnes, a member of the Additive Manufacturing Team, 3D-printed a maze for training with a boroscope, a small device with a camera and light used to inspect small spaces such as an aircraft engine. Stock Photo

RM2NH7WTK–U.S. Air Force Tech. Sgt. Aaron Barnes, 86th Maintenance Squadron aircraft metals technology craftsman, previews a file to 3D print at Ramstein Air Base, Germany, July 21, 2022. Barnes, a member of the Additive Manufacturing Team, 3D-printed a maze for training with a boroscope, a small device with a camera and light used to inspect small spaces such as an aircraft engine.

team of engineers with laptop Stock Photo

RF2H38K10–team of engineers with laptop

U.S. Air Force Tech. Sgt. Aaron Barnes, 86th Maintenance Squadron aircraft metals technology craftsman, displays a metal aircraft bracket and a 3D-printed aircraft bracket made by the Additive Manufacturing Team at Ramstein Air Base, Germany, July 7, 2022. Barnes, a member of the nine-person team, collaborates with his teammates to fix broken, damaged or missing equipment and parts throughout RAB. Stock Photo

RM2MCNRG8–U.S. Air Force Tech. Sgt. Aaron Barnes, 86th Maintenance Squadron aircraft metals technology craftsman, displays a metal aircraft bracket and a 3D-printed aircraft bracket made by the Additive Manufacturing Team at Ramstein Air Base, Germany, July 7, 2022. Barnes, a member of the nine-person team, collaborates with his teammates to fix broken, damaged or missing equipment and parts throughout RAB.

worker showing colleague a 3d printer Stock Photo

RF2A7ACJ0–worker showing colleague a 3d printer

SAN DIEGO (Feb. 7, 2018) Chief of Naval Operations (CNO) Adm. John Richardson tours the Southwest Regional Maintenance Center (SWRMC) Mobile Innovation Center (MIC). The MIC is an additive manufacturing mobile training center where Sailors and Navy Team members can turn ideas into prototypes. SWRMC provides intermediate level maintenance support and selective maintenance training to over 100 surface ships, submarines, shore activities and other commands of the U.S. Pacific Fleet. (U.S. Navy Stock Photo

RMM42FM3–SAN DIEGO (Feb. 7, 2018) Chief of Naval Operations (CNO) Adm. John Richardson tours the Southwest Regional Maintenance Center (SWRMC) Mobile Innovation Center (MIC). The MIC is an additive manufacturing mobile training center where Sailors and Navy Team members can turn ideas into prototypes. SWRMC provides intermediate level maintenance support and selective maintenance training to over 100 surface ships, submarines, shore activities and other commands of the U.S. Pacific Fleet. (U.S. Navy

RM2R114FA–(230511) -- BEIJING, May 11, 2023 (Xinhua) -- This photo taken on April 24, 2023 shows the lunar samples received by the Beijing Institute of Technology. The Beijing Institute of Technology (BIT) recently received 500 mg of the lunar samples brought back by the Chang'e-5 mission. The research team with BIT will study the material characteristics of these samples and also related additive manufacturing technology, with the building of a future lunar research station in mind.TO GO WITH 'Across China: Chinese scientists to explore lunar construction materials, technology' (Xinhua/Zhao Xu)

RM2RRR768–230511 -- BEIJING, May 11, 2023 -- This photo taken on April 24, 2023 shows the lunar samples received by the Beijing Institute of Technology. The Beijing Institute of Technology BIT recently received 500 mg of the lunar samples brought back by the Chang e-5 mission. The research team with BIT will study the material characteristics of these samples and also related additive manufacturing technology, with the building of a future lunar research station in mind. TO GO WITH Across China: Chinese scientists to explore lunar construction materials, technology CHINA-BEIJING-BIT-LUNAR SAMPLECN Zhao

U.S. Air Force Tech. Sgt. Justin Woody, 86th Maintenance Squadron aircraft metals technology non-commissioned officer in charge, displays a 3D-printed knob for an aircraft radio created by the Additive Manufacturing Team at Ramstein Air Base, Germany, July 7, 2022. The team saves the Air Force time and money by printing replacement parts, ultimately allowing Airmen to dedicate their resources to other areas. Stock Photo

RM2MCNRH9–U.S. Air Force Tech. Sgt. Justin Woody, 86th Maintenance Squadron aircraft metals technology non-commissioned officer in charge, displays a 3D-printed knob for an aircraft radio created by the Additive Manufacturing Team at Ramstein Air Base, Germany, July 7, 2022. The team saves the Air Force time and money by printing replacement parts, ultimately allowing Airmen to dedicate their resources to other areas.

U.S. Marine Corps Maj. Ramon Vasquez, an aircraft maintenance engineer officer with Marine Aviation Logistics Squadron 49, Marine Aircraft Group 49, 4th Marine Aircraft Wing, judges a 3D-printed fuse breaker during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that enables Marines to produce innovative solutions, solve maintenance issues, and dev Stock Photo

RM2MC400X–U.S. Marine Corps Maj. Ramon Vasquez, an aircraft maintenance engineer officer with Marine Aviation Logistics Squadron 49, Marine Aircraft Group 49, 4th Marine Aircraft Wing, judges a 3D-printed fuse breaker during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that enables Marines to produce innovative solutions, solve maintenance issues, and dev

RMM42FM2–SAN DIEGO (Feb. 7, 2018) Chief of Naval Operations (CNO) Adm. John Richardson tours the Southwest Regional Maintenance Center (SWRMC) Mobile Innovation Center (MIC). The MIC is an additive manufacturing mobile training center where Sailors and Navy Team members can turn ideas into prototypes. SWRMC provides intermediate level maintenance support and selective maintenance training to over 100 surface ships, submarines, shore activities and other commands of the U.S. Pacific Fleet. (U.S. Navy

RM2MC400Y–U.S. Marine Corps Maj. Ramon Vasquez, an aircraft maintenance engineer officer with Marine Aviation Logistics Squadron 49, Marine Aircraft Group 49, 4th Marine Aircraft Wing, judges a 3D-printed tool during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that enables Marines to produce innovative solutions, solve maintenance issues, and develop cap

ARLINGTON, Va. (March 15, 2017) - John Fiore (left), Technical Director for Naval Surface Warfare Center (NSWC) Dahlgren Division, listens as Harry Whittaker (right), the team lead for NSWC Carderock Division's Sailor Performance Support Technology, and Kevin Lin, a member of Carderock's Disruptive Technology Lab, demonstrate prototypes created for the Big Area Additive Manufacturing Test Article of the Optionally Manned Technology Demonstrator during the 3D Print-a-Thon hosted by the Department of the Navy at the Pentagon. Stock Photo

RMR8YN1N–ARLINGTON, Va. (March 15, 2017) - John Fiore (left), Technical Director for Naval Surface Warfare Center (NSWC) Dahlgren Division, listens as Harry Whittaker (right), the team lead for NSWC Carderock Division's Sailor Performance Support Technology, and Kevin Lin, a member of Carderock's Disruptive Technology Lab, demonstrate prototypes created for the Big Area Additive Manufacturing Test Article of the Optionally Manned Technology Demonstrator during the 3D Print-a-Thon hosted by the Department of the Navy at the Pentagon.

U.S. Marine Corps Master Sgt. Christophe Croteau, an avionics chief with Marine Aviation Logistics Squadron 49, Marine Aircraft Group 49, 4th Marine Aircraft Wing, measures tape during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that enables Marines to produce innovative solutions, solve maintenance issues, and develop capabilities to defeat ne Stock Photo

RM2MC15N1–U.S. Marine Corps Master Sgt. Christophe Croteau, an avionics chief with Marine Aviation Logistics Squadron 49, Marine Aircraft Group 49, 4th Marine Aircraft Wing, measures tape during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that enables Marines to produce innovative solutions, solve maintenance issues, and develop capabilities to defeat ne

Dr. John Fiore (left), Technical Director for Naval Surface Warfare Center, Dahlgren Division, listens as Harry Whittaker (right), the team lead for NSWC Carderock Division's Sailor Performance Support Technology, and Kevin Lin, a member of Carderock's Disruptive Technology Lab, demonstrate prototypes created for the Big Area Additive Manufacturing (BAAM) Test Article of the Optionally Manned Technology Demonstrator (OMTD) during the 3D Print-a-Thon, an event hosted by the Navy at the Pentagon on March 15, 2017. Stock Photo

RMR8YH2J–Dr. John Fiore (left), Technical Director for Naval Surface Warfare Center, Dahlgren Division, listens as Harry Whittaker (right), the team lead for NSWC Carderock Division's Sailor Performance Support Technology, and Kevin Lin, a member of Carderock's Disruptive Technology Lab, demonstrate prototypes created for the Big Area Additive Manufacturing (BAAM) Test Article of the Optionally Manned Technology Demonstrator (OMTD) during the 3D Print-a-Thon, an event hosted by the Navy at the Pentagon on March 15, 2017.

U.S. Marine Corps Lance Cpl. Gregory Bogdan, an aircraft hydraulic mechanic, and Maj. Tom O’Bryon, an aviation supply officer, both with Marine Aviation Logistics Squadron 49, Marine Aircraft Crew 49, 4th Marine Aircraft Wing, design a bridge concept during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that enables Marines to produce innovative s Stock Photo

RM2MC15HX–U.S. Marine Corps Lance Cpl. Gregory Bogdan, an aircraft hydraulic mechanic, and Maj. Tom O’Bryon, an aviation supply officer, both with Marine Aviation Logistics Squadron 49, Marine Aircraft Crew 49, 4th Marine Aircraft Wing, design a bridge concept during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that enables Marines to produce innovative s

QUANTICO, Virginia (Sept. 28, 2016) Jonathan Hopkins, a member of the Additive Manufacturing Tiger Team and employee of Naval Surface Warfare Center, Carderock Division, holds up a 3-D printed symbol at the Modern Day Marine Expo at Marine Corps Base Quantico, Va. This symbol represents Naval Sea Systems Command, Naval Aviation Systems Command, Marine Corps Systems Command, the Marine Corps Warfighting Laboratory, and Marine Corps Headquarters, Installations and Logistics Department, all of which collaborated on an additive manufacturing parts demonstration at the expo. Stock Photo

RMP83175–QUANTICO, Virginia (Sept. 28, 2016) Jonathan Hopkins, a member of the Additive Manufacturing Tiger Team and employee of Naval Surface Warfare Center, Carderock Division, holds up a 3-D printed symbol at the Modern Day Marine Expo at Marine Corps Base Quantico, Va. This symbol represents Naval Sea Systems Command, Naval Aviation Systems Command, Marine Corps Systems Command, the Marine Corps Warfighting Laboratory, and Marine Corps Headquarters, Installations and Logistics Department, all of which collaborated on an additive manufacturing parts demonstration at the expo.

U.S. Marine Corps Lance Cpl. Lauren Miller, a helicopter dynamic components mechanic, and Cpl. Diante Johnson, a mobile facility technician, both with Marine Aviation Logistics Squadron 49, Marine Aircraft Group 49, 4th Marine Aircraft Wing, inspect a computer-aided design software concept during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that Stock Photo

RM2MC151T–U.S. Marine Corps Lance Cpl. Lauren Miller, a helicopter dynamic components mechanic, and Cpl. Diante Johnson, a mobile facility technician, both with Marine Aviation Logistics Squadron 49, Marine Aircraft Group 49, 4th Marine Aircraft Wing, inspect a computer-aided design software concept during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that

QUANTICO, Va. (Sept. 28, 2016) Marine Sgt. Stephen Cook, a legal service specialist with Headquarters Marine Corps, Judge Advocate Division, and amateur hobbyist 3-D printer, and Jonathan Hopkins, a member of the Additive Manufacturing Tiger Team and employee of Naval Surface Warfare Center, Carderock Division, discuss 3-D printed parts at the Modern Day Marine Expo at Marine Corps Base Quantico, Va. Naval Sea Systems Command, Naval Aviation Systems Command, Marine Corps Systems Command, the Marine Corps Warfighting Laboratory, and Marine Corps Headquarters, Installations and Logistics Departm Stock Photo

RMP83177–QUANTICO, Va. (Sept. 28, 2016) Marine Sgt. Stephen Cook, a legal service specialist with Headquarters Marine Corps, Judge Advocate Division, and amateur hobbyist 3-D printer, and Jonathan Hopkins, a member of the Additive Manufacturing Tiger Team and employee of Naval Surface Warfare Center, Carderock Division, discuss 3-D printed parts at the Modern Day Marine Expo at Marine Corps Base Quantico, Va. Naval Sea Systems Command, Naval Aviation Systems Command, Marine Corps Systems Command, the Marine Corps Warfighting Laboratory, and Marine Corps Headquarters, Installations and Logistics Departm

RM2MC164W–U.S. Marine Corps Master Sgt. Christophe Croteau, an avionics chief with Marine Aviation Logistics Squadron 49, Marine Aircraft Group 49, 4th Marine Aircraft Wing, builds a bridge concept with tape and straws during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that enables Marines to produce innovative solutions, solve maintenance issues, and de

NATIONAL HARBOR, Md., (Apr. 3, 2017) Space and Naval Warfare Systems Center Pacific (SSC Pacific) engineers, Jessica L. Watson and Patrick A. Groves, explain how their team designed a 3-D printed antenna to Benjamin Bouffard, mechanical engineer, Chief of Naval Operations, Naval Surface Warfare Center Carderock Division at the Navy League Sea-Air-Space Symposium. Groves’ team was selected to present their 3-D printed models at Sea-Air-Space by the Navy Research and Development Establishment after presenting their work at the Pentagon during a Print-a-Thon highlighting additive manufacturing in Stock Photo

RMR7THME–NATIONAL HARBOR, Md., (Apr. 3, 2017) Space and Naval Warfare Systems Center Pacific (SSC Pacific) engineers, Jessica L. Watson and Patrick A. Groves, explain how their team designed a 3-D printed antenna to Benjamin Bouffard, mechanical engineer, Chief of Naval Operations, Naval Surface Warfare Center Carderock Division at the Navy League Sea-Air-Space Symposium. Groves’ team was selected to present their 3-D printed models at Sea-Air-Space by the Navy Research and Development Establishment after presenting their work at the Pentagon during a Print-a-Thon highlighting additive manufacturing in

RM2MC151W–U.S. Marine Corps Master Sgt. Christophe Croteau, an avionics chief with Marine Aviation Logistics Squadron 49, Marine Aircraft Group 49, 4th Marine Aircraft Wing, measures a 3D-printed model with a caliper during an advanced additive manufacturing course at Stewart Air National Guard Base, Newburgh, N.Y., June 23, 2022. The Marine Innovation Unit and the II Marine Expeditionary Force (MEF) Innovation Campus mobile training team, staffed by U.S. Marines with 2nd Marine Logistics Group, facilitated training that enables Marines to produce innovative solutions, solve maintenance issues, and deve

180207-N-AT895-206 SAN DIEGO (Feb. 7, 2018) Chief of Naval Operations (CNO) Adm. John Richardson tours the Southwest Regional Maintenance Center (SWRMC) Mobile Innovation Center (MIC). The MIC is an additive manufacturing mobile training center where Sailors and Navy Team members can turn ideas into prototypes. SWRMC provides intermediate level maintenance support and selective maintenance training to over 100 surface ships, submarines, shore activities and other commands of the U.S. Pacific Fleet. (U.S. Navy photo by Mass Communication Specialist 1st Class Nathan Laird/Released) Stock Photo

RMM407BH–180207-N-AT895-206 SAN DIEGO (Feb. 7, 2018) Chief of Naval Operations (CNO) Adm. John Richardson tours the Southwest Regional Maintenance Center (SWRMC) Mobile Innovation Center (MIC). The MIC is an additive manufacturing mobile training center where Sailors and Navy Team members can turn ideas into prototypes. SWRMC provides intermediate level maintenance support and selective maintenance training to over 100 surface ships, submarines, shore activities and other commands of the U.S. Pacific Fleet. (U.S. Navy photo by Mass Communication Specialist 1st Class Nathan Laird/Released)

The additive manufacturing process involves depositing thin layers of composite materials on top of each other. AFRL Composite Materials and Processing team researchers used the ultra-bright X-ray at the National Synchrotron Light Source II at Brookhaven National Laboratory to gain better insight into the bonding of composite layers during the additive manufacturing process. Stock Photo

RMPWXJEY–The additive manufacturing process involves depositing thin layers of composite materials on top of each other. AFRL Composite Materials and Processing team researchers used the ultra-bright X-ray at the National Synchrotron Light Source II at Brookhaven National Laboratory to gain better insight into the bonding of composite layers during the additive manufacturing process.

180207-N-AT895-172 SAN DIEGO (Feb. 7, 2018) Chief of Naval Operations (CNO) Adm. John Richardson tours the Southwest Regional Maintenance Center (SWRMC) Mobile Innovation Center (MIC). The MIC is an additive manufacturing mobile training center where Sailors and Navy Team members can turn ideas into prototypes. SWRMC provides intermediate level maintenance support and selective maintenance training to over 100 surface ships, submarines, shore activities and other commands of the U.S. Pacific Fleet. (U.S. Navy photo by Mass Communication Specialist 1st Class Nathan Laird/Released) Stock Photo

RMM407BF–180207-N-AT895-172 SAN DIEGO (Feb. 7, 2018) Chief of Naval Operations (CNO) Adm. John Richardson tours the Southwest Regional Maintenance Center (SWRMC) Mobile Innovation Center (MIC). The MIC is an additive manufacturing mobile training center where Sailors and Navy Team members can turn ideas into prototypes. SWRMC provides intermediate level maintenance support and selective maintenance training to over 100 surface ships, submarines, shore activities and other commands of the U.S. Pacific Fleet. (U.S. Navy photo by Mass Communication Specialist 1st Class Nathan Laird/Released)

Tad Sylivant, augmented reality project lead, and Paul Charron, additive manufacturing engineering lead for FRCE’s advanced technology and innovation team, watch as Rob Thompson performs a vacuum bag leak check on a composite wet layup repair for a class he is recording using an augmented reality headset. Thompson and Charron are wearing two different types of AR headset under consideration for use at FRCE. Stock Photo

RM2H0CXD4–Tad Sylivant, augmented reality project lead, and Paul Charron, additive manufacturing engineering lead for FRCE’s advanced technology and innovation team, watch as Rob Thompson performs a vacuum bag leak check on a composite wet layup repair for a class he is recording using an augmented reality headset. Thompson and Charron are wearing two different types of AR headset under consideration for use at FRCE.

Tobyhanna Army Depot personnel use additive manufacturing technology to fabricate hundreds of clips for advanced respiratory protection systems worn by medical professionals at the Wilkes-Barre VA Medical Center. The clips, which hold replaceable shields on the respiratory systems, were created using state-of-the-art equipment in the depot’s engineering analysis and solutions lab that opened last year. Team Tobyhanna collaborated with medical technicians to establish requirements for producing the components. Stock Photo

RM2H0ETR7–Tobyhanna Army Depot personnel use additive manufacturing technology to fabricate hundreds of clips for advanced respiratory protection systems worn by medical professionals at the Wilkes-Barre VA Medical Center. The clips, which hold replaceable shields on the respiratory systems, were created using state-of-the-art equipment in the depot’s engineering analysis and solutions lab that opened last year. Team Tobyhanna collaborated with medical technicians to establish requirements for producing the components.

Camp Pendleton, Calif. - U.S. Marine Cpl. Tyler Anglin from 1st Maintenance Battalion holds a 3D printed universal load stud wrench during a demonstration event at Marine Corps Tactical Systems Support Activity, on Camp Pendleton, California, April 5-9, 2021. MCTSSA hosted a team of design experts who tested the network connectivity of the portable expeditionary fabrication lab, a self-contained, transportable additive manufacturing lab that can deploy with battalion-level Marine maintenance units. Stock Photo

RM2GKHY7B–Camp Pendleton, Calif. - U.S. Marine Cpl. Tyler Anglin from 1st Maintenance Battalion holds a 3D printed universal load stud wrench during a demonstration event at Marine Corps Tactical Systems Support Activity, on Camp Pendleton, California, April 5-9, 2021. MCTSSA hosted a team of design experts who tested the network connectivity of the portable expeditionary fabrication lab, a self-contained, transportable additive manufacturing lab that can deploy with battalion-level Marine maintenance units.

During COVID-19 restrictions, the research team established protocols and routines that allow remote sample manipulation and data acquisition. From left to right: Dr. Hilmar Koerner, Cornell staff scientists Drs. Louisa Smieska and Arthur Woll, and AFRL Materials and Manufacturing research scientists Dr. Edward Trigg and Mr. Andrew Abbott. The black command window with code lines (upper left) shows the UNIX-based software package for instrument control and data collection SPEC. Users can run their own software packages written in the programming language python to position the sample stage and Stock Photo

RM2GKC3RR–During COVID-19 restrictions, the research team established protocols and routines that allow remote sample manipulation and data acquisition. From left to right: Dr. Hilmar Koerner, Cornell staff scientists Drs. Louisa Smieska and Arthur Woll, and AFRL Materials and Manufacturing research scientists Dr. Edward Trigg and Mr. Andrew Abbott. The black command window with code lines (upper left) shows the UNIX-based software package for instrument control and data collection SPEC. Users can run their own software packages written in the programming language python to position the sample stage and

Lauren Sencio, Ship Self Defense System Hardware Design Task Planning Lead, checks the fit of the front plate of a 3D-printed arming unit May 25, at Naval Surface Warfare Center Dahlgren Division Dam Neck Activity in Virginia Beach, Virginia. The SSDS Hardware Design Team worked with DNA’s FIRE Lab to 3D print the arming unit—a component of the SSDS Command Control Group console—to speed up design validation for the prototype. Stock Photo

RM2GKM025–Lauren Sencio, Ship Self Defense System Hardware Design Task Planning Lead, checks the fit of the front plate of a 3D-printed arming unit May 25, at Naval Surface Warfare Center Dahlgren Division Dam Neck Activity in Virginia Beach, Virginia. The SSDS Hardware Design Team worked with DNA’s FIRE Lab to 3D print the arming unit—a component of the SSDS Command Control Group console—to speed up design validation for the prototype.

WRIGHT-PATTERSON AIR FORCE BASE, Ohio— Dr. Dan Berrigan points to an embedded antenna on an MQ-9 aircraft part made possible through functional applications of additive manufacturing. Flexible circuits, embedded antennas and sensors are just a few of the potential manufacturing capabilities his team is exploring using additive technology. Stock Photo

RMRBA8PC–WRIGHT-PATTERSON AIR FORCE BASE, Ohio— Dr. Dan Berrigan points to an embedded antenna on an MQ-9 aircraft part made possible through functional applications of additive manufacturing. Flexible circuits, embedded antennas and sensors are just a few of the potential manufacturing capabilities his team is exploring using additive technology.

Lauren Sencio, Ship Self Defense System Hardware Design Task Planning Lead, and Kevin Newcomer, an SSDS Hardware Design Team computer engineer, test a 3D-printed arming unit May 25, at Naval Surface Warfare Center Dahlgren Division Dam Neck Activity in Virginia Beach, Virginia. The SSDS Hardware Design Team worked with DNA’s FIRE Lab to 3D print the arming unit—a component of the SSDS Command Control Group console—to speed up design validation for the prototype. Stock Photo

RM2GKM01G–Lauren Sencio, Ship Self Defense System Hardware Design Task Planning Lead, and Kevin Newcomer, an SSDS Hardware Design Team computer engineer, test a 3D-printed arming unit May 25, at Naval Surface Warfare Center Dahlgren Division Dam Neck Activity in Virginia Beach, Virginia. The SSDS Hardware Design Team worked with DNA’s FIRE Lab to 3D print the arming unit—a component of the SSDS Command Control Group console—to speed up design validation for the prototype.

WRIGHT-PATTERSON AIR FORCE BASE, Ohio – One of the most notable, recent projects by the Flexible Materials and Processes team is the transition of 3-D printed conformal antennas to enable Link-16 radio communication on the MQ-9 reaper platform. The team’s expertise in additive manufacturing and functional materials enabled them to create a quick-turn solution to meet a communication need for the Air National Guard. (U.S. Air Force courtesy photo/released) Stock Photo

RMMN0P0Y–WRIGHT-PATTERSON AIR FORCE BASE, Ohio – One of the most notable, recent projects by the Flexible Materials and Processes team is the transition of 3-D printed conformal antennas to enable Link-16 radio communication on the MQ-9 reaper platform. The team’s expertise in additive manufacturing and functional materials enabled them to create a quick-turn solution to meet a communication need for the Air National Guard. (U.S. Air Force courtesy photo/released)

The AFRL Polymer Matrix Composite Materials and Processing team was granted the opportunity to work in collaboration with beamline scientists at the National Synchrotron Light Source II at Brookhaven National Laboratory, allowing them the opportunity to gain an unprecedented view into the behavior of additive manufacturing materials and processes. (U.S. Air Force photo/Hilmar Koerner) Stock Photo

RMP6B6TC–The AFRL Polymer Matrix Composite Materials and Processing team was granted the opportunity to work in collaboration with beamline scientists at the National Synchrotron Light Source II at Brookhaven National Laboratory, allowing them the opportunity to gain an unprecedented view into the behavior of additive manufacturing materials and processes. (U.S. Air Force photo/Hilmar Koerner)

RMMTJP63–WRIGHT-PATTERSON AIR FORCE BASE, Ohio— Dr. Dan Berrigan points to an embedded antenna on an MQ-9 aircraft part made possible through functional applications of additive manufacturing. Flexible circuits, embedded antennas and sensors are just a few of the potential manufacturing capabilities his team is exploring using additive technology. (U.S. Air Force photo by Marisa Alia-Novobilski/released)

U.S. Marine Corps Chief Warrant Officer 2 Daniel Bower, weapons repair officer with 1st Maintenance Battalion, shows Lt. Gen. Michael Dana, deputy commandant, Installations and Logistics, the progress the Expeditionary Manufacturing team has made with 3-D Metal printing at Camp Pendleton, Calif., Dec. 8, 2017. Through additive manufacturing, the team was able to print impeller fans used to remove debris from the air-filter of the M1-Abrams tank. The EX-Man is able to repair or replace mission critical parts used throughout the Marine Corps in a forward deployed environment. (U.S. Marine Corps Stock Photo

RMKPYECK–U.S. Marine Corps Chief Warrant Officer 2 Daniel Bower, weapons repair officer with 1st Maintenance Battalion, shows Lt. Gen. Michael Dana, deputy commandant, Installations and Logistics, the progress the Expeditionary Manufacturing team has made with 3-D Metal printing at Camp Pendleton, Calif., Dec. 8, 2017. Through additive manufacturing, the team was able to print impeller fans used to remove debris from the air-filter of the M1-Abrams tank. The EX-Man is able to repair or replace mission critical parts used throughout the Marine Corps in a forward deployed environment. (U.S. Marine Corps

RMMT8A4B–The additive manufacturing process involves depositing thin layers of composite materials on top of each other. AFRL Composite Materials and Processing team researchers used the ultra-bright X-ray at the National Synchrotron Light Source II at Brookhaven National Laboratory to gain better insight into the bonding of composite layers during the additive manufacturing process. (U.S. Air Force photo/Harry Pierson)

RMMPK03D–ARLINGTON, Va. (March 15, 2017) - John Fiore (left), Technical Director for Naval Surface Warfare Center (NSWC) Dahlgren Division, listens as Harry Whittaker (right), the team lead for NSWC Carderock Division's Sailor Performance Support Technology, and Kevin Lin, a member of Carderock's Disruptive Technology Lab, demonstrate prototypes created for the Big Area Additive Manufacturing Test Article of the Optionally Manned Technology Demonstrator during the 3D Print-a-Thon hosted by the Department of the Navy at the Pentagon. (U.S. Navy photo by Kelley Stirling/Released)

WRIGHT-PATTERSON AIR FORCE BASE, Ohio – Brig. Gen. Stacey T. Hawkins, Director, Logistcs, Engineering and Force Protection, Air Mobility Command (left) and Dr. Donna C. Senft, Chief Scientist, Air Mobility Command, along with core members of the aircraft maintenance team visited the Materials and Manufacturing Directorate, Air Force Research Laboratory, to gain in-depth knowledge of additive manufacturing capabilities and technologies, Aug. 26. The visit included a directorate overview, discussions on additive manufacturing applications and visits to multiple research laboratories, highlightin Stock Photo

RMP333KP–WRIGHT-PATTERSON AIR FORCE BASE, Ohio – Brig. Gen. Stacey T. Hawkins, Director, Logistcs, Engineering and Force Protection, Air Mobility Command (left) and Dr. Donna C. Senft, Chief Scientist, Air Mobility Command, along with core members of the aircraft maintenance team visited the Materials and Manufacturing Directorate, Air Force Research Laboratory, to gain in-depth knowledge of additive manufacturing capabilities and technologies, Aug. 26. The visit included a directorate overview, discussions on additive manufacturing applications and visits to multiple research laboratories, highlightin

WRIGHT-PATTERSON AIR FORCE BASE, Ohio – Brig. Gen. Stacey T. Hawkins, Director, Logistcs, Engineering and Force Protection, Air Mobility Command (right) and Dr. Donna C. Senft, Chief Scientist, Air Mobility Command, along with core members of the AMC aircraft maintenance team visited the Materials and Manufacturing Directorate, Air Force Research Laboratory, to gain in-depth knowledge of additive manufacturing capabilities and technologies, Aug. 26. The visit included a directorate overview, discussions on additive manufacturing applications and visits to multiple research laboratories, highli Stock Photo

RMP333KN–WRIGHT-PATTERSON AIR FORCE BASE, Ohio – Brig. Gen. Stacey T. Hawkins, Director, Logistcs, Engineering and Force Protection, Air Mobility Command (right) and Dr. Donna C. Senft, Chief Scientist, Air Mobility Command, along with core members of the AMC aircraft maintenance team visited the Materials and Manufacturing Directorate, Air Force Research Laboratory, to gain in-depth knowledge of additive manufacturing capabilities and technologies, Aug. 26. The visit included a directorate overview, discussions on additive manufacturing applications and visits to multiple research laboratories, highli

RMMPHPFF–Dr. John Fiore (left), Technical Director for Naval Surface Warfare Center, Dahlgren Division, listens as Harry Whittaker (right), the team lead for NSWC Carderock Division's Sailor Performance Support Technology, and Kevin Lin, a member of Carderock's Disruptive Technology Lab, demonstrate prototypes created for the Big Area Additive Manufacturing (BAAM) Test Article of the Optionally Manned Technology Demonstrator (OMTD) during the 3D Print-a-Thon, an event hosted by the Navy at the Pentagon on March 15, 2017. (U.S. Navy photo by Kelley Stirling/Released)

An iRobot 310 Small Unmanned Ground Vehicle belonging to Combat Logistic Battalion 31, 31st Marine Expeditionary Unit, sits staged with 3-D printed lens covers aboard the USS Wasp (LHD-1) while underway in the Pacific Ocean, April 17, 2018. Marines with CLB-31 are now capable of ‘additive manufacturing,’ also known as 3-D printing, which is the technique of replicating digital 3-D models as tangible objects. The 31st Marine Expeditionary Unit partners with the Navy’s Amphibious Squadron 11 to form the Wasp Amphibious Ready Group, a cohesive blue-green team capable of accomplishing a variety o Stock Photo

RMME31DD–An iRobot 310 Small Unmanned Ground Vehicle belonging to Combat Logistic Battalion 31, 31st Marine Expeditionary Unit, sits staged with 3-D printed lens covers aboard the USS Wasp (LHD-1) while underway in the Pacific Ocean, April 17, 2018. Marines with CLB-31 are now capable of ‘additive manufacturing,’ also known as 3-D printing, which is the technique of replicating digital 3-D models as tangible objects. The 31st Marine Expeditionary Unit partners with the Navy’s Amphibious Squadron 11 to form the Wasp Amphibious Ready Group, a cohesive blue-green team capable of accomplishing a variety o

RMME31DC–An iRobot 310 Small Unmanned Ground Vehicle belonging to Combat Logistic Battalion 31, 31st Marine Expeditionary Unit, sits staged with 3-D printed lens covers aboard the USS Wasp (LHD-1) while underway in the Pacific Ocean, April 17, 2018. Marines with CLB-31 are now capable of ‘additive manufacturing,’ also known as 3-D printing, which is the technique of replicating digital 3-D models as tangible objects. The 31st Marine Expeditionary Unit partners with the Navy’s Amphibious Squadron 11 to form the Wasp Amphibious Ready Group, a cohesive blue-green team capable of accomplishing a variety of

WRIGHT-PATTERSON AIR FORCE BASE, Ohio –A member of the Flexible Materials and Processes team at the Air Force Research Laboratory’s Materials and Manufacturing Directorate exhibits an additively manufactured electrical circuit embedded in a flexible material substrate. The flex team is exploring novel ways to use 3-D printing technology to create next generation flexible hybrid technologies for the Air Force. (U.S. Air Force photo by Marisa Alia-Novobilski/released) Stock Photo

RMMN0P0X–WRIGHT-PATTERSON AIR FORCE BASE, Ohio –A member of the Flexible Materials and Processes team at the Air Force Research Laboratory’s Materials and Manufacturing Directorate exhibits an additively manufactured electrical circuit embedded in a flexible material substrate. The flex team is exploring novel ways to use 3-D printing technology to create next generation flexible hybrid technologies for the Air Force. (U.S. Air Force photo by Marisa Alia-Novobilski/released)

PANAMA CITY, Florida - The Naval Surface Warfare Center Panama City Division MK29 Underwater Breathing Apparatus Project Team receives NAVSEA Excellence Awards Aug. 28, 2017 for their efforts in the reduction of production costs and schedule through the innovative use of additive manufacturing to print complex components for life support equipment. U.S. Navy Photo by Anthony Powers (Released) 170828-N-CD100-022 Stock Photo

RMMN3E76–PANAMA CITY, Florida - The Naval Surface Warfare Center Panama City Division MK29 Underwater Breathing Apparatus Project Team receives NAVSEA Excellence Awards Aug. 28, 2017 for their efforts in the reduction of production costs and schedule through the innovative use of additive manufacturing to print complex components for life support equipment. U.S. Navy Photo by Anthony Powers (Released) 170828-N-CD100-022

Additive Manufacturing (AM) Tiger Team member Michael Britt-Crane (left) helps student interns at Naval Surface Warfare Center, Carderock Division, put the finishing touches on their watertight proof-of-concept vehicles in the David Taylor Model Basin during the inaugural Naval Sea Systems Command Additive Manufacturing (AM) Challenge in West Bethesda, Md., July 28, 2016. (U.S. Navy photo by Dustin Q. Diaz/Released) Stock Photo

RMP3XDB6–Additive Manufacturing (AM) Tiger Team member Michael Britt-Crane (left) helps student interns at Naval Surface Warfare Center, Carderock Division, put the finishing touches on their watertight proof-of-concept vehicles in the David Taylor Model Basin during the inaugural Naval Sea Systems Command Additive Manufacturing (AM) Challenge in West Bethesda, Md., July 28, 2016. (U.S. Navy photo by Dustin Q. Diaz/Released)

PANAMA CITY, Florida - The Naval Surface Warfare Center Panama City Division Disruptive Technology Lab BAAM Optionally Manned Demonstrator Team Dr. John Camperman, left, and Garrett Leavitt, right, receives Naval Sea Systems Command Most Innovative Excellence Awards Aug. 28, 2017 for their use of innovative engineering and additive manufacturing to develop vehicle shell based on the SEAL Delivery Vehicle that, ultimately, can be operated unmanned or manned. U.S. Navy Photo by Anthony Powers (Released) 170828-N-CD100-020 Stock Photo

RMMN3E70–PANAMA CITY, Florida - The Naval Surface Warfare Center Panama City Division Disruptive Technology Lab BAAM Optionally Manned Demonstrator Team Dr. John Camperman, left, and Garrett Leavitt, right, receives Naval Sea Systems Command Most Innovative Excellence Awards Aug. 28, 2017 for their use of innovative engineering and additive manufacturing to develop vehicle shell based on the SEAL Delivery Vehicle that, ultimately, can be operated unmanned or manned. U.S. Navy Photo by Anthony Powers (Released) 170828-N-CD100-020

Jonathan Hopkins, a mechanical engineer and Additive Manufacturing (AM) Tiger Team member, shows fellow employees at Naval Surface Warfare Center, Carderock Division objects created through AM during a tour of the new Manufacturing, Knowledge and Education (MAKE) Lab, which officially opened in West Bethesda, Md., March 24, 2016. The MAKE Lab will open training and production in AM, also known as 3-D printing, to all of Carderock's employees who desire to participate and exchange ideas. (U.S. Navy photo by Dustin Q. Diaz/Released) Stock Photo

RMPAEN16–Jonathan Hopkins, a mechanical engineer and Additive Manufacturing (AM) Tiger Team member, shows fellow employees at Naval Surface Warfare Center, Carderock Division objects created through AM during a tour of the new Manufacturing, Knowledge and Education (MAKE) Lab, which officially opened in West Bethesda, Md., March 24, 2016. The MAKE Lab will open training and production in AM, also known as 3-D printing, to all of Carderock's employees who desire to participate and exchange ideas. (U.S. Navy photo by Dustin Q. Diaz/Released)

Jonathan Hopkins, a member of the Additive Manufacturing Tiger Team and employee of Naval Surface Warfare Center, Carderock Division, holds up a 3-D printed symbol at the Modern Day Marine Expo at Marine Corps Base Quantico, Va. This symbol represents Naval Sea Systems Command, Naval Aviation Systems Command, Marine Corps Systems Command, the Marine Corps Warfighting Laboratory, and Marine Corps Headquarters, Installations and Logistics Department, all of which collaborated on an additive manufacturing parts demonstration at the expo. (U.S. Navy photo by Dustin Q. Diaz/Released) Stock Photo

RMP2HMXR–Jonathan Hopkins, a member of the Additive Manufacturing Tiger Team and employee of Naval Surface Warfare Center, Carderock Division, holds up a 3-D printed symbol at the Modern Day Marine Expo at Marine Corps Base Quantico, Va. This symbol represents Naval Sea Systems Command, Naval Aviation Systems Command, Marine Corps Systems Command, the Marine Corps Warfighting Laboratory, and Marine Corps Headquarters, Installations and Logistics Department, all of which collaborated on an additive manufacturing parts demonstration at the expo. (U.S. Navy photo by Dustin Q. Diaz/Released)

RMMCCP85–180207-N-AT895-206 SAN DIEGO (Feb. 7, 2018) Chief of Naval Operations (CNO) Adm. John Richardson tours the Southwest Regional Maintenance Center (SWRMC) Mobile Innovation Center (MIC). The MIC is an additive manufacturing mobile training center where Sailors and Navy Team members can turn ideas into prototypes. SWRMC provides intermediate level maintenance support and selective maintenance training to over 100 surface ships, submarines, shore activities and other commands of the U.S. Pacific Fleet. (U.S. Navy photo by Mass Communication Specialist 1st Class Nathan Laird/Released)

RMMCCP8K–180207-N-AT895-172 SAN DIEGO (Feb. 7, 2018) Chief of Naval Operations (CNO) Adm. John Richardson tours the Southwest Regional Maintenance Center (SWRMC) Mobile Innovation Center (MIC). The MIC is an additive manufacturing mobile training center where Sailors and Navy Team members can turn ideas into prototypes. SWRMC provides intermediate level maintenance support and selective maintenance training to over 100 surface ships, submarines, shore activities and other commands of the U.S. Pacific Fleet. (U.S. Navy photo by Mass Communication Specialist 1st Class Nathan Laird/Released)

Marine Sgt. Stephen Cook, a legal service specialist with Headquarters Marine Corps, Judge Advocate Division, and amateur hobbyist 3-D printer, and Jonathan Hopkins, a member of the Additive Manufacturing Tiger Team and employee of Naval Surface Warfare Center, Carderock Division, discuss 3-D printed parts at the Modern Day Marine Expo at Marine Corps Base Quantico, Va. Naval Sea Systems Command, Naval Aviation Systems Command, Marine Corps Systems Command, the Marine Corps Warfighting Laboratory, and Marine Corps Headquarters, Installations and Logistics Department collaborated on an additive Stock Photo

RMP2HMYK–Marine Sgt. Stephen Cook, a legal service specialist with Headquarters Marine Corps, Judge Advocate Division, and amateur hobbyist 3-D printer, and Jonathan Hopkins, a member of the Additive Manufacturing Tiger Team and employee of Naval Surface Warfare Center, Carderock Division, discuss 3-D printed parts at the Modern Day Marine Expo at Marine Corps Base Quantico, Va. Naval Sea Systems Command, Naval Aviation Systems Command, Marine Corps Systems Command, the Marine Corps Warfighting Laboratory, and Marine Corps Headquarters, Installations and Logistics Department collaborated on an additive

RMMDWN8A–U.S. Marine Corps Chief Warrant Officer 2 Daniel Bower, weapons repair officer with 1st Maintenance Battalion, shows Lt. Gen. Michael Dana, deputy commandant, Installations and Logistics, the progress the Expeditionary Manufacturing team has made with 3-D Metal printing at Camp Pendleton, Calif., Dec. 8, 2017. Through additive manufacturing, the team was able to print impeller fans used to remove debris from the air-filter of the M1-Abrams tank. The EX-Man is able to repair or replace mission critical parts used throughout the Marine Corps in a forward deployed environment. (U.S. Marine Corps

RMMJK4DH–U.S. Marine Corps Chief Warrant Officer 2 Daniel Bower, weapons repair officer with 1st Maintenance Battalion, shows Lt. Gen. Michael Dana, deputy commandant, Installations and Logistics, the progress the Expeditionary Manufacturing team has made with 3-D Metal printing at Camp Pendleton, Calif., Dec. 8, 2017. Through additive manufacturing, the team was able to print impeller fans used to remove debris from the air-filter of the M1-Abrams tank. The EX-Man is able to repair or replace mission critical parts used throughout the Marine Corps in a forward deployed environment. (U.S. Marine Corps

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