A German industrial plant will be the first to receive locally generated wind power through a direct connection.
With the green energy from the four new wind turbines installed by project partner SL NaturEnergie, thyssenkrupp Hohenlimburg, a subsidiary of thyssenkrupp Steel, can now cover 40% of its average annual electricity requirements.
The four wind turbines, each up to 160 meters in height and with a rotor diameter of 138 meters, are connected to the thyssenkrupp Hohenlimburg plant network via a direct line a good 3 kilometers in length. The wind farm generates over 55 million kilowatt hours annually, allowing the majority of this energy to be used directly without relying on the public grid. Surplus quantities are only supplied to other Group sites via the public grid in the event of high wind speeds or lower demand at the plant.
For gun barrels, tempering is essential to bring steel to the necessary hardness. But what equipment is needed, and how is this done under a nitrogen cover gas? Explore how low-oxygen temper furnaces — often electrically heated — accomplish this feat.
This article by Mike Grande was originally published inHeat Treat Today’sMay 2024 Sustainable Heat Treat Technologies 2024print edition.
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Steel tempering is a heat treatment process that involves heating the steel to a specific temperature and holding it at temperature for a specific time to improve its mechanical properties. Tempering is most commonly performed on steel that has been hardened by quenching. Quenched steel is too brittle for most uses, and so it must be tempered to bring the hardness down to the desired level, giving the steel the desired balance between strength, toughness, and ductility.
Steel is tempered in an oven (often referred to as a “temper furnace”) at temperatures of roughly 350°F to 1300°F, with the exact temperature dependent on the alloy and the desired hardness and toughness. This heating process creates a layer of oxide scale on the surface of the tempered steel, which is unsightly, can weaken it, and can lead to failure or damage. Further, the scale can directly interfere with the intended use of the steel parts. Although in many applications this surface oxidation is not a detriment (it may be removed in a subsequent operation for example), it is not acceptable for certain steel parts.
In order to prevent surface oxidation during tempering, the oxygen can be removed from the oven using nitrogen injected into the heating chamber. More specifically, the nitrogen acts as a protective “cover gas” by displacing the oxygen, reducing the percentage of oxygen in the heating chamber. Essentially, the nitrogen dilutes the oxygen in the oven until it is brought down to a low concentration, such that very little oxidation can occur, preserving the surface quality of the tempered steel.
Gun barrels, for example, are tempered to remove the residual stresses from rifling and other prior processes and bring the steel down to the required hardness.
The tempering process involves heating the barrel to a specific temperature in a nitrogen atmosphere which is very low in oxygen. This helps prevent oxidation and other unacceptable surface contamination that would weaken the steel and make it unsuitable for the rigors of shooting. The internal barrel pressure during the firing of an AR15 rifle, for example, can reach 60,000 PSIG, which generates the 2,200 pounds of force required to produce the typical 3,000 feet per second (2,000 miles per hour) muzzle velocity. Considering these operating conditions and the temperature cycling experienced by the barrels, the tempering process must be performed precisely, and it must be very repeatable. This requires a carefully designed furnace engineered specifically for low-oxygen tempering under a nitrogen cover gas.
Design of the Low-Oxygen Temper Furnace
The key features of a properly designed temper furnace are a tightly sealed shell, a robust heating and recirculation system, a nitrogen delivery and control system, and an atmosphere-controlled cooling arrangement.
The shell of the controlled-atmosphere temper furnace must be tightly sealed so that the factory air, which contains oxygen, is prohibited from mixing with the heated environment inside the furnace. Air contains about 21% oxygen, and if it gets into the interior of the furnace during heating, this oxygen will quickly cause oxidation of the steel. This requires the heating chamber itself to be designed and manufactured with tight tolerances to prevent uncontrolled entrainment of air into the furnace and leaking of the nitrogen cover gas out of the furnace.
Low-oxygen temper furnaces are most commonly electrically heated, and the wall penetrations for the heaters are designed with special seals to preserve the low-oxygen furnace atmosphere. The same is true for the penetrations to accommodate the thermocouples and other sensors, the cooling system, and the door. Special attention must be given to the door opening, and the door itself. As the interface between the hot furnace interior and the room temperature factory environment, it is especially prone to warping, which will allow leaks. There are different technologies used to combat this, including double door seals, water cooled seals, and clamps to squeeze the door against the furnace opening.
Figure 1. Nitrogen temper furnace with a load/unload table
As with a conventional non-atmosphere temper furnace, the heating and recirculation system must be designed with a high recirculation rate and a sufficiently robust heating system to aggressively and evenly transfer the heat to the load of steel. The furnace manufacturer will do calculations to ensure the heaters are sufficiently sized to heat the loaded oven within the desired time, and this is an important part of the technical specification for anyone purchasing a temper furnace. Otherwise, the equipment may not be able to maintain the required production rate.
One of the most critical parts of the atmosphere temper furnace is the nitrogen control system. The idea is to inject sufficient nitrogen into the heating chamber to maintain the reduced oxygen level, and no more than that. Th e most effective design uses a sensor to continuously measure the oxygen level in the furnace, and a closed-loop control system to regulate the flow of nitrogen into it. It is important the nitrogen is high purity (that it contains a sufficiently low oxygen level), and that it is sufficiently dry, as moisture in the heating chamber can greatly increase the likelihood of oxidation.
The process starts by purging the furnace with nitrogen to establish the required low-oxygen environment. Sufficient nitrogen is introduced to the furnace to bring the oxygen level down to the percentage required to heat the parts without undo oxidation. Each time a quantity of nitrogen equal to the interior furnace volume is injected into it, it is considered one “air change.” The number of air changes employed is determined by the desired oxygen concentration in the furnace, with five air changes being a common rule of thumb.
Figure 2. Purging the furnace with nitrogen to reduce the oxygen concentration
Purging is complete when sufficient nitrogen has been injected into the furnace to reduce the oxygen purity to the desired level. The nitrogen flow is then reduced to the minimum required to replace any nitrogen leaking out of the furnace. Some furnace designs simply flood the furnace with a high volume of nitrogen in an uncontrolled manner. Although effective at reducing the oxygen concentration, these systems can waste a profuse amount of nitrogen since it is used at an unregulated rate. A nitrogen control system, therefore, is advisable.
After the load is heated up and soaked at temperature for the required time, the furnace must be cooled down. In an ordinary non-nitrogen furnace, the door is simply opened, or a damper system is actuated, allowing cool factory air into the furnace, while exhausting the heated air. A nitrogen atmosphere temper furnace, however, must remain tightly sealed with the door closed, until the temperature is reduced to below the oxidation temperature, commonly 300°F to 400°F, aft er which the door can be opened. Since the equipment utilizes a well-insulated, tightly sealed design, it would take many hours, or even days, to cool sufficiently without a forced cooling system. For this reason, nitrogen temper furnaces must employ a sealed cooling system that cools the furnace without introducing factory air. This is done with a heat exchanger used to separate the reduced-oxygen furnace atmosphere from the cooling media, which is air or water.
Figure 3. Rear-mounted cooling system
The most effective style of cooling system uses cooling water passing through one side of the heat exchanger and the furnace atmosphere passing through the other. The heat exchanger is mounted to the rear exterior of the furnace, and the furnace atmosphere is conveyed through the exchanger, with dampers included to start and stop the atmosphere flow, thereby starting and stopping the cooling action. There are also systems available that pass cooling air through the exchanger, rather than water. Although less expensive, they provide a much slower cooling rate, which greatly increases the cooling time and reduces the production rate of the equipment, as fewer loads can be processed on an annual basis.
Nitrogen Tempering for Materials Other Than Steel
Some metals other than steel are heat processed in a low-oxygen nitrogen environment, while others do not benefit from this process.
Pure copper can be processed under a nitrogen cover gas to reduce oxidation during heating. If the oxygen concentration is not low enough, spotting of the material can occur, where black, sooty spots appear on the surface. Copper is much less sensitive than steel to moisture in the heating chamber. Copper alloys, such as brass or bronze, are not suitable for processing in a nitrogen atmosphere due to a phenomenon known as dezincification, which removes zinc from the alloy, weakening the material and turning it a yellow color. Titanium is not processed with nitrogen, as “nitrogen pickup” (a nitrogen contamination of the titanium) will occur. Aluminum can be processed under a low-oxygen nitrogen atmosphere to some benefit, which slows down the growth of surface oxidation during heating, but not to the degree experienced with steel.
About the Author
Mike Grande,
Vice President
of Sales,
Wisconsin Oven
Corporation
Mike Grande has a 30+ year background in the heat processing industry, including ovens, furnaces, and infrared equipment. He has a BS in mechanical engineering from University of Wisconsin-Milwaukee and received his certification as an Energy Manager (CEM) from the Association of Energy Engineers in 2009. Mike is the vice president of Sales at Wisconsin Oven Corporation.
For more information: Contact sales@wisoven.com.
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NGC Gears, a manufacturer of wind power gearboxes, has completed the installation of two additional Endothermic generators from a manufacturer with North American locations.
UPC-Marathon, a Nitrex company, installed the Endo generators at NGC Gears‘ its new facility in Jinhu, China. This acquisition brings the total of generator sets to five since 2022, collectively generating an impressive 800 m³/h (22,252 ft3/h) capacity of Endothermic gas supplied to carburizing and hardening furnaces used for processing various gear components. The latest installations in February and March of 2024 support the heat treating operations of the company’s wind energy gearbox production.
NGC’s decision to expand capacity is in response to the growing demand for wind power solutions in China and globally. The new Endothermic gas generating systems will significantly enhance the company’s production capabilities, enabling NGC to meet increasing market needs with greater efficiency and reliability.
EndoFlex generators from UPC-Marathon (Source: Nitrex)
EndoFlex offers precise control of production media to the carburizing and hardening environments, leading to higher quality gear production with improved longevity and performance. The result is improved carburizing and hardening processes, higher-quality hardened gears, reduced operating costs, and increased efficiency, as well as immediate cost savings through reduced electricity and gas consumption and minimized waste.
Johnny Xu, general manager at UPC-Marathon China, shared, “The latest EndoFlex investments align with NGC’s development of low-consumption, high-efficiency gearbox products for large-scale onshore and offshore wind turbines.”
This press release is available in its original form here.
IperionX Limited and Vegas Fastener Manufacturing, LLC (Vegas Fastener) have agreed to partner to develop and manufacture titanium alloy fasteners and precision components with IperionX’s advanced titanium products.
The commercial focus of this partnership is on developing and manufacturing titanium alloy fasteners and precision components for the U.S. Army Ground Vehicle Systems Center (GVSC), which is the United States Armed Forces’ research and development facility for advanced technology in ground systems. GSVC’s research and development includes robotics, autonomy, survivability, power, mobility, intelligent systems, maneuver support and sustainment.
Additionally, the partners will design, engineer and produce titanium fasteners for critical sectors such as the aerospace, naval, oil & gas, power generation, pulp & paper and chemical sectors. These sectors demand fasteners that provide not only high strength-to-weight ratios but also exceptional corrosion resistance for high-performance applications.
Vegas Fastener, headquartered in Las Vegas, Nevada, is a global leader in the development and manufacturing of high-performance fasteners and custom machined components. Together with its allied company, PowerGen Components, Vegas Fastener serves a diverse array of customers in the defense, marine, power generation, oil & gas, nuclear, chemical, and water infrastructure sectors. Vegas Fastener develops and manufactures precision high-performance fasteners using specialized alloys to meet demanding quality specifications.
IperionX’s leading titanium technology portfolio includes high-performance near-net shape titanium products, semi-finished titanium products, spherical titanium powder for additive manufacturing and metal injection molding, and angular titanium powder for a wide range of advanced manufacturing applications. These innovative patented technologies allow for sustainability and process energy efficiencies over the traditional Kroll titanium production process.
Image above: High-performance fasteners manufactured by Vegas Fastener
This press release is available in its original form here.
A custom-built vacuum induction melting (VIM) equipment is set to expand thermal processing for a manufacturer, whose operations already has two VIM solutions.
The furnace will be fabricated at the Buffalo headquarters of Retech, a SECO/WARWICK Group subsidiary, to capitalize on available schedule improvements. As custom equipment, the subsidiary’s furnaces are not dependent on assembly-line style construction, so they can be fabricated and assembled just in either location.
While this client prefers not to divulge this VIM’s application, Retech’s solution can handle casting a wide range of materials used in applications from automotive and consumer products to critical, high-value equiaxed, directionally solidified, or single-crystal aerospace parts. Almost every furnace Retech makes is modified to meet the specifications and associated applications of its clients.
VIM from the Retech Buffalo, NY location.
Source: SECO/WARWICK
Mike Moyer Vice President of Sales, Solar Atmospheres, Eastern PA
Solar Atmospheres of Souderton PA commissioned a new vacuum furnace capable of utilizing high pressure gas quenching (HPGQ) at 20-Bar (about 300 PSI) to meet demanding cooling rate specifications for the heat treatment of nickel-based superalloys in the aerospace and power generation industries.
The vacuum furnace, manufactured by sister company Solar Manufacturing, has a working hot zone of 24” x 24” x 72” and utilizes unique hot zone design features to increase the quench rate. The furnace is rated for operation to 2400°F and temperature uniformity plus/minus 10°F.
Mike Moyer, vice president of Sales at Solar Atmospheres comments, “The furnace utilizes a 600-HP cooling motor and fan with a creative gas nozzle design to maximize gas flow as it moves through the hot zone and the heat exchanger and back across the workload.”
The full press release from Solar Atmospheres is available upon request.
A technology research institute has chosen a heat treat vacuum furnace which will support research and development in the fields of materials engineering and machine construction and operation.
SECO/WARWICK will supply a Vector® vacuum furnace with high-pressure gas hardening and will include options for vacuum carburizing, pre-nitriding for carburizing technology, low-pressure nitriding (LPN), and low-pressure carbonitriding (LPCN).
This configuration provides precision performance in vacuum, ensuring steel detail surfaces are protected, and the ability to carry out hardening processes through the use of high cooling gas pressures (15 bar).
The small vacuum furnace will have a working space of 400x400x600 mm. With a round heating chamber, the furnace, despite its small size, can be used to test and perform research on many sizes of parts including work with large dimensions.
Says Sławomir Woźniak, CEO of the SECO/WARWICK Group, "We cooperate with scientific institutions all over the world because we are aware that industry development depends on their work. Many groundbreaking discoveries have already been made, but I am sure that many more are yet to come."
The R&D institute deals with methods of refining metal products by increasing their corrosion resistance and increasing mechanical properties, especially fatigue strength and resistance to wear in friction processes. The technological institute strives to disseminate and apply in practice the results of scientific research and development work, develops new technologies, and conducts service activities.
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Two new specialist technology focused businesses, Lake City Heat Treat and Stack Metallurgical Group, have been acquired by Bodycote.
Bodycote has agreed to acquire Lake City Heat Treat based in Warsaw, Indiana, a Medical market HIP and vacuum heat treatment business; and Stack Metallurgical Group based in the Pacific Northwest of the U.S., a key provider of HIP, heat treatment and metal finishing services.
The businesses are complementary to the commercial heat treater’s existing operations and will both expand its geographic footprint in North America and provide additional customer reach. Comprising of two HIP and three heat treatment sites, the businesses will be integrated into Bodycote’s existing specialist technologies business and aerospace, defense and energy classical heat treatment business respectively.
Stephen Harris, Group Chief Executive of Bodycote plc, commented, “These investments are an important and exciting enabler of our strategy to further enhance and grow our Specialist Technologies businesses. In addition, they will also expand our footprint in Aerospace and Medical heat treatment on the West Coast and in Indiana in the U.S."
The heat treater also announced plans to open a new HIP plant utilizing one of their existing sites in greater Los Angeles. The capacity is intended to support the rapid growth in space and civil aviation markets in the Los Angeles area.
The combined gross consideration for the acquisitions is 119 million pounds ($145 million) on a cash and debt free basis. The net economic consideration is approximately 106 million pounds ($130 million).
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A manufacturer for the energy industry has recently announced the installment of a roller hearth furnace system. The heat treat system is comprised of two (2) box furnaces with quench tanks, a dual directional load transfer car, four (4) companion draw batch ovens, and two (2) stationary load/unload tables.
The system from Lindberg/MPH has a maximum operating temperature of 1850°F for the box furnaces, which are designed for nitrogen-based atmosphere applications. The load space dimensions of the box furnaces are 48” W x 96” D x 36” H, with larger internal chambers to provide clearance for baskets or fixtures. A snake chain pusher assembly with a dual-directional pacecar is used by each furnace to transfer the loads from the chamber to the pneumatically operating quench elevator deck.
The glycol quench tanks are designed for quick and uniform quenching, featuring an immersion oil heater and an externally mounted air-to-quench media heat exchanger. The tanks’ agitation systems include four agitators with draft tubes. The gross load capacity of the car is 10,000 lbs., and it travels linearly in front of the equipment on two embedded floor rails.
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Siemens Energy, a recognized manufacturer of gas turbines and other energy technologies, has selected an eco-friendly vacuum furnace with high-pressure gas hardening (6 bar abs.) and high vacuum for one of its production facilities.
The vacuum furnace from SECO/WARWICK, known as Vector®, will execute efficient and ecologically clean processes in a high vacuum range. Consisting of a dry pump, a Root’s pump, and five Oerlikon/Leybold turbomolecular pumps, the furnace will meet the manufacturer's restrictive requirements.
Maciej Korecki
Vice President of Business of the Vacuum Furnace Segment
SECO/WARWICK
(Source: SECO/WARWICK)
The Vector also contains a metal heating chamber, which prevents direct heat loss to the vacuum chamber’s wall and ensures high process purity. The efficiency is also influenced by the ability to conduct the heating and cooling process at 6 bars with two gases (nitrogen or argon).
Maciej Korecki, vice president of the Vacuum Segment at the SECO/WARWICK Group, states, “This is our first order from a Siemens Energy production facility, but in the past, we have supplied equipment to gas turbine manufacturers."
Commenting on the future of clean energy for the power industry, Korecki further notes, "Gas turbines can run on a variety of gases, including hydrogen. Green hydrogen, as an energy carrier without a carbon footprint, will gradually increase its market share not only in the energy industry, but also in other economic sectors, contributing to gradual decarbonization of the atmosphere."
