A technology-based manufacturer of aerospace and defense parts and systems recently expanded its capability to develop and produce metal alloy additive manufacturing parts for aerospace and power systems through the acquisition of AM provider which services the aerospace, defense, medical, and industrial markets.
Eileen Drake, CEO and president of Aerojet Rocketdyne
Aerojet Rocketdyne Holdings, Inc. has acquired 3D Material Technologies (3DMT) from ARC Group Worldwide, Inc., complementing Aerojet Rocketdyne’s industry-leading capabilities to develop and produce metal alloy additive manufacturing parts for aerospace propulsion and power systems. Aerojet Rocketdyne has qualified production parts for the RL10 and RS-25 liquid rocket engines and continues to develop and demonstrate the benefits of additive manufacturing for its hypersonic propulsion systems.
“The addition of 3DMT’s capacity and expertise in metal alloy additive manufacturing expands our range of products and services in the space and defense markets,” said Eileen Drake, CEO and president of Aerojet Rocketdyne. “As we look to the future, additive manufacturing will continue to play an important role in lowering costs and production timelines. This deal allows Aerojet Rocketdyne to broaden its application of this revolutionary technology. We respect the long-standing reputation for quality and customer focus that 3DMT has built in the aerospace industry and we are thrilled to welcome them to our company.”
3DMT will continue to operate with its existing workforce at its 28,000 square ft. facility located in Daytona Beach, Florida.
Main photo credit/caption: Aerojet Rocketdyne / Hot-fire test of Aerojet Rocketdyne’s ISE-100 thruster conducted at the company’s Redmond, Washington test facility
A commercial heat treat company which is approved to heat treat certain flight critical and flight safety configurations for prime aerospace and helicopter companies recently invested in a new Universal Batch Quench (UBQ) furnace and a Universal Batch Temper (UBTN) annealing furnace to be operated at its plant in Fraser, Michigan.
Tracy Dougherty, VP Sales, AFC-Holcroft
“We’re excited to be a part of the continued growth and expansion of Specialty Steel Treating,” said Tracy Dougherty, Vice President of Sales at AFC-Holcroft. “The customization of these furnaces combined with state of the art controls and IoT features (Remote Diagnostics™), enable both AFC-Holcroft and Specialty Steel Treating the ability to offer superior quality, performance and continuous improvement to customers.”
Delivery of the UBTN is expected in the 2nd quarter of 2019 to the Specialty Steel Treating site on Malyn Road in Fraser, with the UBQ to follow in the 3rd quarter to the Commerce Road plant, also located in Fraser.
Heat TreatToday recently announced the launch of the Leaders in AerospaceHeat TreatLinkedIn Group — with a special drawing for $100 Amazon gift cards. This was on the heels of releasing our inaugural Leaders in Aerospace Heat Treat monthly e-newsletter and the new AerospaceHeat Treat special print/digital edition (click here for digital).
Leaders in AerospaceHeat Treat LinkedIn Group (click here) provides a professional-level space where heat treaters from the aerospace industry can discuss issues and ideas. Heat TreatTodaywill regularly provide content related to the group, keeping members current on the latest technologies, products, processes, and discussions. If you’re a heat treat leader in the aerospace industry, you should be in this group.
As a special welcome to founding members of the Leaders in AerospaceHeat Treat LinkedIn Group, Heat TreatTodayis conducting a drawing for three winners, each will receive a $100 Amazon gift cards Anyone who joins the group AND comments on any of the posts during the month of April (through April 30, 2019) will be entered into the drawing.
Share the love: forward this invitation to Leaders in AerospaceHeat Treat LinkedIn Group and news about the Amazon contest to any others you feel may benefit.
Go to your LinkedIn account, sign in and search for “Leaders in Aerospace Heat Treat.” Join the group and connect with other leaders in aerospace heat treat.
For more information about the Leaders in AerospaceHeat Treat monthly e-newsletter, contact Doug Glenn at doug@heattreattoday.com.
It’s a busy week here at Heat TreatToday. We are announcing the launch of the Leaders in AerospaceHeat TreatLinkedIn Group — with a special drawing for $100 Amazon gift cards — as well as our inaugural Leaders in AerospaceHeat Treat monthly e-newsletter, both on the heels of the new AerospaceHeat Treat special print/digital edition (click here for digital).
Leaders in AerospaceHeat Treat LinkedIn Group (click here) provides a professional-level space where heat treaters from the aerospace industry can discuss issues and ideas. Heat TreatTodaywill regularly provide content related to the group, keeping members current on the latest technologies, products, processes, and discussions. If you’re a heat treat leader in the aerospace industry, you should be in this group.
As a special welcome to founding members of the Leaders in AerospaceHeat Treat LinkedIn Group, Heat TreatTodayis conducting a drawing for three winners, each will receive a $100 Amazon gift cards Anyone who joins the group AND comments on any of the posts during the month of April (through April 30, 2019) will be entered into the drawing.
Share the love: forward this invitation to Leaders in AerospaceHeat Treat LinkedIn Group and news about the Amazon contest to any others you feel may benefit.
Go to your LinkedIn account, sign in and search for “Leaders in Aerospace Heat Treat.” Join the group and connect with other leaders in aerospace heat treat.
For more information about the Leaders in Aerospace Heat Treat monthly e-newsletter, contact Doug Glenn at doug@heattreattoday.com.
A leading aerospace engine and components company based in Mobile, Alabama recently partnered with a global heat treat specialist to improve its nitriding and annealing processes with plasma nitriding technology.
Continental Aerospace Technologies™ (formerly Continental Motors), which is recognized for manufacturing piston engines for small aircraft, sought to improve its nitriding systems with high ammonia emissions and turned to RÜBIG Industrial Furnaces, an Austrian metal hardening company. RÜBIG supplied two “EVEREST 100/180 Duo” plasma nitriding and annealing furnaces, as well as a cleaning solution. The equipment provides independent multi-heating and cooling zones and the Micropuls® technology.
The first ever Nadcap accreditation for Aero Structure Assembly has been awarded to an aerospace company based in Wichita, Kansas.
Lee Aerospace Inc., which designs, manufactures, installs, and repairs aerospace parts and assemblies for the aerospace industry, recently received the accreditation following a 2018 pilot audit that validated the audit criteria developed by the Nadcap Aero Structure Assembly Task Group and rigorously assessed the company’s compliance to the applicable industry standards and customer requirements.
Christopher Lowe of Spirit AeroSystems, Nadcap Aero Structure Assembly Task Group Chair
“There are more companies than ever involved in aerostructure assembly as activity is delegated through the supply chain by the airframers,” explained Christopher Lowe of Spirit AeroSystems, Nadcap Aero Structure Assembly Task Group Chair. “As a result, the need for supply chain oversight in this area was recognized as being of growing importance. Nonconforming assembly practices can cause serious escapes such as unseen product defects, delivery delays and rectification costs.
“Congratulations to Lee Aerospace Inc. for their notable achievement in being the first in the world to gain this prestigious accreditation. I am pleased to have had the opportunity, through Nadcap, to work with my peers at Airbus, Airbus Defense and Space, Arconic, BAE Systems, Helicomb International, Lee Aerospace Inc., Leonardo, Lockheed Martin, Northrop Grumman and Spirit AeroSystems to address this issue and I encourage others in the industry to get involved in this activity.”
Technologies covered in the Aero Structure Assembly audit criteria currently extend to fastening, electrical bonding, bushing and bearing installation, and sealant application.
Tommy Howland, Director of Quality for Lee Aerospace
Issuing the first accreditation is a significant step in the maturation of the newest Nadcap Task Group, whose members have been working towards this point since 2015 when the Nadcap Management Council approved Aero Structure Assembly as one of the specialized technologies that Nadcap accredits. Aero Structure Assembly now joins both long-standing practices such as heat treating, welding, and non-destructive testing, as well as newer activities such as composites and electronics in the Nadcap program.
“As an active member of Nadcap, when the opportunity to be the first company for accreditation in a pilot program presented itself, we literally jumped at the chance,” said Tommy Howland, Director of Quality for Lee Aerospace. “At Lee Aerospace, we strive to be the best in all aspects of our manufacturing processes, including transparencies, composites, and aerostructure assembly.”
The space industry is growing fast and is predicted to be worth over a trillion dollars by 2040.
Keith Ferguson, Senior Business Development Manager at Morgan Advanced Materials’ Braze Alloys Business, explains how braze alloys play their part in safe, reliable and sustainable space exploration.
A Braze New World
The saying goes, “one small step for man, one giant leap for mankind.” This famous phrase uttered by Neil Armstrong is the perfect advertisement for space exploration and its importance to the future.
Less than a century old, space exploration has come on leaps and bounds since the first artificial satellite, Sputnik 1, was propelled into space in 1957. Since then, the world has witnessed marvels such as landing on the moon, the space shuttle program of the 1970s, and the launch of the International Space Station.
The importance of these missions and their subsequent value is immeasurable. Many might not realize on a day-to-day basis how space exploration has improved lives and the global economy to no end. This includes simple weather forecasting, broadcasting TV and radio, predicting natural disasters, monitoring for fertile land, forecasting sea level patterns, and even aiding research in muscular atrophy.
It’s little wonder then that this industry has significant value. The space industry was reportedly worth $384 million USD in 2017, growing at a rate of 7.4 percent. According to Morgan Stanley, it sees the industry growing to be worth $1.1 trillion USD by 2040.
However, there are challenges. Many believe that the millions of dollars and resources used to explore space could be better used on immediate threats to society like clean water, famine, poverty and more. Outside of external opinion though, there are internal operational challenges. Namely, space exploration needs to become safer and more sustainable.
A huge part of solving this challenge is in brazing alloys.
A Brief History on Brazing in Space
In simple terms, brazing joins two metals by heating and melting a filler (alloy) that bonds to the two pieces of metal and joins them. The filler must have a melting temperature below that of the metal pieces.
The use of braze alloys in space equipment is mission critical, as they allow sensors to be mounted as close as possible to engines to measure and monitor output and feed data back to operators. Indeed, they’ve already aided successful missions. Two of Morgan Advanced Materials’ braze alloys, RI-46 and RI-49, were specifically engineered and used by NASA on the Space Shuttle Main Engine, also known as the RS25.
Braze Alloys (Morgan in Space)
RI-46 specifically was developed as a replacement for the existing Nioro braze alloy, which is comprised of 82/18 Au/Ni (gold/nickel). RI-46 contains much less gold, adding in copper and manganese instead. This helped make the braze alloy significantly less dense and provided crucial weight savings, but also still operable from a wide range of temperatures, between -400°F to 1292°F (-240°C to 700°C).
These alloys have not only been critical for past space missions, but also for future missions. RI-46 and RI-49 have been adopted for NASA’s Space Launch System (SLS), a vehicle that is planned to take a crewed mission to Mars.
As alluded to already, developing new braze alloys is as much about performance as well as sustainability.
The Need for Non-Precious Alloys
It needs no mention that space exploration is a costly exercise. According to NASA, the average cost to launch a Space Shuttle is $450 million per mission. The Space Shuttle Endeavour, the orbiter built to replace the Space Shuttle Challenger, cost an eye-watering $1.7 billion USD.
Wire Form Braze Alloys (Morgan in Space)
Bringing costs down is clearly required to keep space missions feasible. One key part of cost reduction is in reducing the use of precious metal braze alloys.
Precious metals like gold and palladium are becoming increasingly scarce. Of course, the cost of producing alloys from these precious metals is also increasing as a result.
However, there can be a reluctance to come away from using precious metal alloys. Years of research, development, and data mean these alloys are tested and reliable. When dealing with missions and equipment that run into the hundreds of millions of dollars and, more importantly, the lives of crew members, reliability becomes an overarching objective, and failures must be prevented.
To solve this issue, Morgan’s Braze Alloys business has been researching and developing non-precious metal alloys over many years. As seen from the RI-46 and RI-49 alloys, these solutions are just as strong as their equivalent high precious-metal counterparts, but at a fraction of the cost.
Non-precious metal alloys can be made from metals like nickel, chromium, and cobalt. Their success has already been seen in the aerospace sector, and now research is being pioneered into making them fit for going into orbit and beyond.
Space, for All to Enjoy
Space travel is not just for highly trained astronauts and public benefit; there is also a growing commercial aspect. Satellite TV and radio have already been mentioned, but billionaire entrepreneurs such as Richard Branson and Elon Musk have also been pioneering private space travel. The hope is that civilians might one day be able to enjoy outer space as well, albeit at potentially high prices.
Achieving this dream is of course hinged on safety and reliability, given that lives will be at stake. The key to improving these factors is being able to place sensors as close as possible to the spacecraft’s engine.
By enabling sensors to be placed near the spacecraft’s engine, mission control and crew can then accurately read and measure data and output. This includes fuel efficiency, temperature, gas flow and monitoring for fire detection or abnormalities. If these sensors are placed too far away from the engines, then data readings become inaccurate and missions can be compromised.
Recent news highlights why sensor technologies are critical, as a two-man space crew had to abort their flight to the ISS after a post-rocket launch failure. The Soyuz spacecraft started to experience failure 119 seconds into the flight, and seemingly, problems were reported by the crew first, not by mission control. The crew described feelings of weightlessness, an indication of a problem during that stage of the flight. Luckily, they aborted, ejected their capsule from the rocket, and returned safely to Earth.
While the cause of the failure is still to be identified at the time of writing, clearly, such a situation should not be happening. Any problems should be picked up by mission control, and not be reliant on crew judgment.
Active Alloys join ceramic sensors to engines. (Morgan in Space)
The challenge though is that some sensors are made from ceramic due to the need to resist corrosion and high temperatures, typically up to 1742°F (950°C ). However, these ceramic sensors then need to be joined to metallic parts of the engine.
This is where “active alloys” come in. Unlike regular braze alloys that join metal to metal, these alloys can join metal to ceramic, or even ceramic to ceramic. Industry standard active alloys like Incusil®-ABA and Ticusil® from Morgan’s range were developed up to 40 years ago but are still in use today. New alloys are also currently in development to withstand much higher temperatures.
A Never-Ending Journey
Morgan Metals and Joining Center of Excellence in Hayward, California (Morgan in Space)
Much like how there is still so much to learn and explore about space, so too is Morgan’s journey with braze alloys. Morgan Advanced Materials is not just committed to making the space industry more sustainable and safer, but it is helping with applications across all industries.
A key pillar of this is through Morgan’s highly specialized Metals and Joining Centre of Excellence (CoE), based in Hayward, California, as well as Morgan’s Brazing Department.
With highly trained researchers and scientists, Morgan’s Braze Alloys business can custom cater alloys to specific applications, run trials to test materials, braze cycles and fixturing. The whole operation, from powder atomization, to preform fabrication and brazing trials, can be looked after from start to finish.
Flexicore® (Morgan in Space)
One of the latest developments being pioneered at the Metals and Joining CoE is Flexicore®. This new technology transforms traditionally brittle alloys (such as AMS4777) into a flexible wire form. In many cases, this will be far superior to pastes in terms of repeatability and ease of use. Along with the operational benefits, Flexicore® will also allow for the use of nickel-based alloys to replace precious-metal alloys. Again, this will help to bring costs down for operators and manufacturers.
Watch This Space
Space travel, as Richard Branson predicts for his own Virgin Galactic programme, is only two or three flights away. We’re truly not far away from entering a new world, and brazing alloys will have their say on how the space industry turns out.
Morgan’s Braze Alloy solutions, like RI-46 and RI-49, as well as others like Palniro-1 and Palniro-7, can already be found across the various programmes and spacecraft. Through more research and development, who knows where this important industry could lead us to.
Morgan Advanced Materials plc is a global engineering company headquartered in Windsor, UK , and is a world leader in advanced materials science and engineering of ceramics, carbon, and composites, engineering high-specification materials, components, and sub-assembly parts to solve challenging technical problems. Markets that Morgan work in include healthcare, petrochemicals, transport, electronics, energy, defense, security and industrial.
Sourcing activity by users of a leading online platform is up in the category of Aerospace Heat Treating.
Tony Uphoff, President and CEO of Thomas
The recent Thomas Index Report, the online platform for supplier discovery and product sourcing in the US and Canada, focuses on sourcing activity for Aerospace Heat Treating as well as related aerospace categories by users of the Thomasnet.com platform. Besides data for Aerospace Contract Manufacturing,
"[O]ur data shows that sourcing activity is also up 18% or more in the related categories of Aerospace Heat Treating and Aerospace Machining." ~ Tony Uphoff
Space technology has caught the attention of dreamers and investors recently, with the launch of Elon Musk’s SpaceX Crew Dragon capsule, which successfully docked with the international space station, and the restart of the mission to the moon.
A heat treating equipment manufacturer based in Carroll, Ohio, recently announced plans to expand its facility and broaden its capability to produce furnaces for aerospace manufacturers equipping in-house heat treat operations.
Delta H Technologies LLC’s investments will cover the purchase of machinery and equipment for the design and production of furnaces for aerospace components. The expansion confirms the company’s nearly 30-year commitment to providing state-of-the-art heat treat equipment manufacturing to keep pace with the growth in aerospace technology and production.
“Richard Conway, director and chief technology officer, started the company in 1990 while attending Ohio State University to get his bachelors of science in industrial engineering. He did maintenance and tuning work for industrial furnaces and ovens. . . . Richard’s wife, Mary Conway, is a retired teacher who taught honors chemistry and physics at Pickerington North High School. And she was the one who came up with the name Delta H as it is a math symbol for change of heat.” ~ Lancaster Eagle-Gazette
An independent provider of engine and airframe maintenance, repair, and overhaul (MRO) services was recently selected by a Ghana-based airline to provide a tailored package of engine services for its fleet of Q400 regional turboprop aircraft.
Under the multi-year contract, StandardAero, based in Scottsdale, Arizona, will provide MRO services for PassionAir’s Pratt & Whitney Canada (P&WC) PW150A turboprop engines from its Designated Overhaul Facility (DOF) in Seletar, Singapore.
The contract will also authorize StandardAero to provide PassionAir with a range of rental engine, engineering and engine condition trend monitoring (ECTM) support services. StandardAero is uniquely placed to offer ECTM analysis expertise as both a P&WC designated overhaul facility (DOF) and a CAMP Systems Designated Analysis Center (DAC).
Peter Turner, President of Airlines & Fleets for StandardAero
“After evaluating prospective service providers on our shortlist, we are happy to engage StandardAero as the engine maintenance provider for our Q400 fleet,” said Charles Richardson, Director of Maintenance for PassionAir. “We found the engine care package offered to be comprehensive and competitive, and it is my belief and hope that we will experience complete satisfaction with the service and support that we anticipate to receive from them.”
“We are pleased to add PassionAir to the list of Ghanaian operators supported by StandardAero,” said Peter Turner, President of Airlines & Fleets for StandardAero. “PassionAir joins a growing list of customers who benefit from service excellence provided by our start-of-the-art facility in Singapore, backed up by our extensive engineering and ECTM capabilities. We look forward to meeting and exceeding the airline’s expectations for on-time support over the coming years.”
