We all know that cooling off the right way matters. Your friend may be hot, but dumping a bucket of ice on them just might cause your friendship to crack. The same applies to heat treating. The methods and modes of cooling operations can make or break our bank and equipment.
Heat TreatToday has coalesced technical information across articles and podcast episodes from key experts, including a case study comparing the efficiency of different cooling technologies, a Heat Treat Radioepisode full of purchasing guidance and the updates on the latest technologies, and finally a helpful comparative of cooling systems for the automotive industry.
Discover more about these three topics in today’s Technical Tuesday original content feature.
Intelligent Cooling System Improves Operations for Alloy Manufacturer: A Case Study
There’s only one constant about technology: It’s always evolving — revealing new innovations and opportunities. And as these new technologies come to light, heat treating operations have new opportunities to reduce cost, increase efficiency, and ensure consistent, optimized part quality, regardless of the job parameters. With the introduction of new process cooling technologies to the heat treating market, previously unexplored systems become viable solutions for unanswered operating challenges. Gary Burdardt, market development manager with Frigel North America, authored a case study to explore new technologies in cooling operations.
“Located on the East Coast, the manufacturer needed to find an alternative process cooling solution for its vacuum furnace cooling operation. It had been using air-cooled chillers, but the costs of continuous operation were too high. Operating as a batch furnace, the heat load of this particular application was specified to be approximately 200 tons, and process cooling water temperature, which was specified at 70°F, presented a significant challenge.”
Heat Treat Radio #100: Cooling Off the Heat (Treat)!
Keeping your heat treat equipment cool is as critical as it is an oxymoron. If you have old cooling systems or are looking to purchase new ones, hear from Matt Reed, director of Sales and Technologies at Dry Coolers, as he shares purchasing considerations, maintenance, and latest technologies with Heat TreatRadio host, Doug Glenn. Learn about the importance of flow, sediment build up, hot spots, and more!
“Vacuum furnaces, around the 1960s and 1970s, when they were being developed, focused on heat treating materials. Cooling is required because you’ve got these inner walled jackets in the furnace, jackets in the heads, you’ve got diffusion pumps, mechanical pumps — all these ancillary pieces of equipment that require cooling. Originally, you could use city water and flow city water right through the furnace. Customers soon find out that that’s a lot of water consumption, so the next step was to look at an evaporative cooling tower. You start recirculating evaporative cooling tower water directly through the furnaces.”
Deciding on a process cooling system for your automotive heat treat requires intentional consideration. In this article Bob Smith, director of product management at Thermal Care, offers practical and valuable guidance on three options: fluid coolers, cooling towers, and chillers.
“When considering which type of process fluid cooling system is best for your automotive heat treat application, it is important to determine the process fluid medium, desired temperature, and the significance of operating cost versus initial investment. There are often multiple solutions to a process cooling application, and the following is intended to provide a basic outline of the types of systems available and where they are best used.”
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.
Find Heat Treating Products And Services When You Search On Heat Treat Buyers Guide.Com
A supplier to the railway industry has ordered a technological line consisting of two vacuum furnaces, three tempering furnaces, and two washers. The line will be utilized for hardening processes of steel parts used in railway rolling stock.
The SECO/WARWICK line for voestalpine Fastening Systems consists of an electric chamber furnace, a washer, a cooling station, and an endothermic atmosphere generator. The hardening process will be carried out in a controlled atmosphere with temperatures up to 1742°F.
Additionally, the technological line includes an electric chamber furnace designed for the heat treatment of steel parts in a protective nitrogen atmosphere at temperatures up to 1292°F, along with a washer, cooling station and endothermic generator. The line will include a loader operating in automatic mode, a set of roller tables and a closed loop water system. The number of the supplied technological line units is selected to ensure the quality of manufactured components.
Mariusz Raszewski, Deputy Director of the Aluminum Process and CAB Furnaces Team, SECO/WARWICK (Source: SECO/WARWICK)
Mariusz Raszewski, deputy director of the Aluminum Process and CAB Furnaces Team at SECO/WARWICK said, “The line is configured in such a way that if the volume of the company products decreases, the customer can also offer commercial processing due to the wide technological spectrum of this main furnace unit.”
The whole solution will be supervised by a master system, which is used for the continuous monitoring of the heat treatment equipment operation and provides advanced data analysis for the production processes.
Mariusz Fogtman, COO, voestalpine Fastening Systems (Source: voestalpine Fastening Systems)
“The universal furnace solution will allow [us] to process details in various configurations,” Mariusz Fogtman, COO of voestalpine Fastening Systems commented. “Apart from technological parameters, it is important for us to limit the processed details’ deformations, which is possible in the ordered solution. SECO/WARWICK presented a partnership and flexible approach to the challenge of this order”
This press release is available in its original form here.
Heat Treat 2019 was just a month ago, and one of the great benefits of gathering with a community of heat treaters is the opportunity to challenge old habits and look at new ways of doing things. Heat TreatToday’s101 Heat TreatTips is another opportunity to learn the tips, tricks, and hacks shared by some of the industry’s foremost experts.
Today’s Technical Tuesday features tips from Grammer Vacuum Technologies covering Vacuum Furnace and Cooilng.
If you have a heat treat-related tip that would benefit your industry colleagues, you can submit your tip(s) to doug@heattreattoday.com or editor@heattreattoday.com.
Heat TreatTip #59
Oxygen Contamination Sources
A common source of oxygen contamination to vacuum furnace systems is in the inert gas delivery system. After installation of the delivery lines, as a minimum, the lines should be pressurized and then soap-bubble tested for leaks. But even better for critical applications is to attach a vacuum pump and helium leak detector to these lines with all valves securely closed, pull a good vacuum, and helium leak check the delivery line system. Helium is a much smaller molecule than oxygen and a helium-tight line is an air-tight line. Also, NEVER use quick disconnect fittings on your inert gas delivery system to pull off inert gas for other applications unless you first install tight shut-off valves before the quick disconnect. When the quick disconnect is not in use, these valves should be kept closed at all times. (Though the line is under pressure, when you open a back-fill valve to a large chamber, the line can briefly go negative pressure and pull in air through a one-way sealing quick disconnect valve.)
Air-cooled vacuum furnace cooling system (from Dry Coolers)
Heat TreatTip #80
Closed-Loop Water Cooling Systems
Modern water cooling systems for vacuum furnaces are typically closed-loop. (By this we mean that air never comes in contact with the water that goes through your vacuum furnace. The expansion tank would be pressurized with dry nitrogen, in this case, to prevent oxygen pick-up by the water.) Sometimes after maintenance work, the expansion tank or sump is left open to air. As a result, air/oxygen, dirt, and organic materials can get into the water system and eventually cause both corrosion and plugging of your chamber. A plugged chamber can overheat and explode or implode causing serious injury or death. Replacement chambers are very expensive. A recirculating water system that allows air to contact the water entering your furnace can dramatically decrease the life of your vacuum chamber.
Heat TreatTip #89
Lanthanated Moly Alloy Strip Increases Element Longevity
Moly and TZM moly grids can double or triple vacuum furnace throughput by using a two-tier or three-tier fixture to utilize unused work zone space.
Pure molybdenum vacuum furnace heating elements distort with time in service due to growth and contraction during thermal cycling. You can often see this distortion beginning just a month or two into service of new elements. Eventually, these will contact either the insulation/shield wall— or worse yet, your parts—and cause electrical arcing. So they need to be replaced before this happens. By making a direct replacement of these pure moly strips with a lanthanated moly alloy strip, the life of the elements can be significantly increased. We have seen a rough doubling of the element life by making this change. Many new OEM vacuum furnaces are now supplied with lanthanated elements at the start. OEM and aftermarket hot zone re-builders are frequently making this change as well to get longer life out of their hot zone elements.
Heat TreatTip #101
TZM Moly Alloy for Structural Vacuum Furnace Components
For over 30 years, there has been a molybdenum alloy called TZM (Moly-0.5%Ti-0.1%Zr) which is far superior to pure molybdenum in vacuum furnace structural applications. TZM is slightly more expensive than pure moly, so OEM furnace companies use pure moly to keep their costs down for competitive reasons. But they could be offering it as an option for their buyers. Pure molybdenum metal undergoes recrystallization at temperatures as low as 2000°F. The recrystallized structure is very brittle at the grain boundaries, resulting in a structural component that also is very brittle. If you have a vacuum furnace with moly components, you have undoubtedly seen this with older parts. TZM alloy, however, does not recrystallize until around 2500°F, and even then it does not exhibit the brittle behavior of pure moly, because the recrystallized grain size is still very fine. TZM is also stronger than pure moly, as much as 3 to 4 times the strength at temperatures above 2000°F. For a 10-15% premium in cost, you can dramatically extend the life of your moly structural components in your furnaces.
During the day-to-day operation of heat treat departments, many habits are formed and procedures followed that sometimes are done simply because that’s the way they’ve always been done. One of the great benefits of having a community of heat treaters is to challenge those habits and look at new ways of doing things. Heat TreatToday‘s 101 Heat TreatTips, tips and tricks that come from some of the industry’s foremost experts, were initially published in the FNA 2018 Special Print Edition, as a way to make the benefits of that community available to as many people as possible. This special edition is available in a digital format here.
Today, we offer one of the tips published under the Cooling Systems category.
Cooling Systems
Heat TreatTip #10
How to Keep Your Cooling System Up and Running
Most cooling system failures are not catastrophic, merely expensive and disruptive. The most common problem is fouling — accumulated dirt, debris, products of corrosion, mineral scale, and bio-films that coat heat transfer surfaces.
Buy equipment that is easy to clean and easy to maintain.
Install filtration equipment to keep systems clean and that help in monitoring for excessive build-up.
Use closed-loop systems for furnace equipment—keep the system sealed, clean, and oxygen-free to control corrosion and fouling.
Install redundant systems—especially pumps, fans, and filters.
Have a backup source of water in the event of power failure (e.g., fuel-fired pumps, municipal water, or electric generator).
