Laser heat treating, a form of case hardening, offers substantial advantages when distortion is a critical concern in manufacturing operations. Traditional heat treating processes often lead to metal distortion, necessitating additional post-finishing operations like hard milling or grinding to meet dimensional tolerances.
This Technical Tuesday article was originally published in first published in Heat Treat Today’sJanuary/February 2024 Air & Atmosphereprint edition.
In laser heat treating, a laser (typically with a spot size ranging from 0.5″ x 0.5″ to 2″ x 2″) is employed to illuminate the metal part’s surface. This results in a precise and rapid delivery of high-energy heat, elevating the metal’s surface to the desired transition temperature swiftly. The metal’s thermal mass facilitates rapid quenching of the heated region resulting in high hardness.
Key Benefits of Laser Heat Treating
Consistent Hardness Depth
Laser heat treatment achieves consistent hardness and hardness depth by precisely delivering high energy to the metal. Multiparameter, millisecond-speed feedback control of temperature ensures exacting specifications are met.
Minimal to Zero Distortion
Due to high-energy density, laser heat treatment inherently minimizes distortion. This feature is particularly advantageous for a variety of components ranging from large automotive dies to gears, bearings, and shafts resulting in minimal to zero distortion.
Precise Application of Beam Energy
Unlike conventional processes, the laser spot delivers heat precisely to the intended area, minimizing or eliminating heating of adjoining areas. This is specifically beneficial in surface wear applications, allowing the material to be hardened on the surface while leaving the rest in a medium-hard or soft state, giving the component both hardness and ductility.
Figure 1. Laser heat treating of automotive stamping die constructed from D6510 cast iron material (Source: Synergy Additive Manufacturing LLC)
No Hard Milling or Grinding Required
The low-to-zero-dimensional distortion of laser heat treatment reduces or eliminates the need for hard milling or grinding operations. Post heat treatment material removal is limited to small amounts removable by polishing. Eliminating hard milling or grinding operations saves substantial costs in the overall manufacturing process of the component. Our typical tool and die customers have seen over 20% cost savings by switching over to laser heat treating.
Any metal with 0.2% or more carbon content is laser heat treatable. Hardness on laser heat treated materials typically reaches the theoretical maximum limit of the material. Many commonly used steels and cast irons in automotive industry such as A2, S7, D2, H13, 4140, P20, D6510, G2500, etc. are routinely laser heat treated. A more exhaustive list of materials is available at synergyadditive.com/laser-heat-treating.
Laser heat treatment is poised to witness increased adoption in the automotive and other metal part manufacturing sectors. The adoption of this process faces no significant barriers, aside from the typical challenges encountered by emerging technologies, such as lack of familiarity, limited hard data, and a shortage of existing suppliers. The substantial savings, measured in terms of cost, schedule, quality, and energy reduction, provide robust support for the continued embrace of laser heat treatment in manufacturing processes.
A U.S.-based engineered knitted wire mesh solutions company and global supplier for the automotive, food service, and janitorial industries will receive a vacuum heat treat furnace. The furnace will be primarily utilized for vacuum annealing materials that are susceptible to adverse effects of their mechanical properties when exposed to any levels of oxygen or nitrogen.
Solar Manufacturing Mentor® Pro Model HFL-3036-2IQ furnace Source: Solar ManufacturingJason Davidson Northeast Regional Sales Manager Solar Source: solarmfg.com
This vacuum furnace features a molybdenum shielded hot zone measuring 18” wide x 18” high x 36” deep. It is capable of operating temperatures up to 2400°F and has a workload weight capacity of up to 1,000 lbs. Additionally, it includes the SolarVac® Essentials PLC-based control system. The internal gas cooling system with a 50 HP drive motor can reach quenching workloads at 2-bar positive pressure in either nitrogen or argon.
Jason Davidson, regional sales manager at Solar Manufacturing, states, “Our customer started running trials with our affiliate commercial heat treater, Solar Atmospheres. Once the trial results proved the heat treat cycle, and the [Mentor® Pro Model HFL-3036-2IQ] furnace demonstrated it could process the required quantities, the customer had confidence to place the purchase order with us.”
This press release is available in its original form here.
Piotr Skarbiński Vice President of Aluminum and CAB Products Segment SECOWARWICK Source: LinkedIn
Two Chinese manufacturers choose EV/CAB lines to expand their heat exchanger production to better heat treat oversized battery cooler.
The furnace supplier, SECO/WARWICK, noted that this will be the fourteenth CAB line for one of the manufacturers in the China market.
“This year, CAB lines for brazing heat exchangers have been sold to several new customers on the Chinese market," said Piotr Skarbiński, vice president of the Aluminum and CAB Products at SECO/WARWICK. “The EV/CAB line . . . [has] temperature uniformity across the belt, suitable for the strict requirements of the automotive industry, as well as its reliability and quality."
Find heat treating products and services when you search on Heat Treat Buyers Guide.com
Two atmosphere controlled retort box furnaces will be used for de-bindering ceramic matrix composite parts (CMC) as well as powder metals processing (PM) and hot isostatic pressing (HIP).
The main function of this L&L Special Furnace Co., Inc. furnace is to remove all organics and other materials used in the product prior to placing in a high fire vacuum chamber in a process called de-bindering: Parts are heated to 1220°F in a retort chamber that is pressurized with nitrogen. The by-products of the outgassing part are directed by pressure and flow out the rear of the furnace. The parts are then heated in a vacuum furnace to temperatures in excess of 2300°F. The result is a component that is stronger and lighter than titanium.
Aerospace and military have always been the key areas that CMC and additive technologies are applied. The CMC development is a key part of the subsonic ordnance project along with multitudes of other military applications. This technology allows for lighter and more durable aircraft, munitions, and body armor versus using some alloy and ceramic substitutes. Automotive has also always had a strong presence in the additive manufacturing industry as well.
It is new application areas were CMC technology is starting to shine. CMC technology is beginning to establish a presence in agricultural applications such as water desalinization, power and battery technology in providing lighter fuel cells. This technology will be applied to battery operated transportation vehicles, not only improving transportation capabilities but also lowering greenhouse emissions.
A heat treater in Ontario, Canada, recently commissioned a 6,600 lb/hr continuous mesh belt atmosphere furnace system from a fellow Canadian furnace manufacturer. CAN-ENG Furnaces International Limited has recently been contracted to design and commission this new system for Metex Heat Treating Limited, which will be commissioned for the hardening and tempering of high-volume automotive critical fasteners, stampings, and assembly components.
6000 lb per hour Mesh Belt Furnace (source: CAN-ENG)
The system includes a computerized loading system, mesh belt controlled atmosphere hardening furnace, oil quench system, mesh belt tempering furnace, and pre- and post wash systems.
This recent furnace design integrates enhancements to the radiant heating system that provides Metex with added capacity within a fixed system footprint. This contract will represent Metex Heat Treating’s 6th CAN-ENG Furnace System, providing Metex with over 400,000 lbs./day of continuous atmosphere processing capacity in addition to batch and induction services, which are provided to customers across Canada and the USA.
The furnace line is scheduled to commission in Q4 of 2020.
(source: CAN-ENG, bardia hashemirad, kartik bhattacharjee, marcus p)
A research organization recently awarded a contract to a North American furnace manufacturer for the supply of a rapid-heating furnace to be used for product development of lightweight hot-stamped and formed aluminum automotive components. This organization will integrate the aluminum-sheet heating furnace with existing equipment to support both automotive manufacturers and Tier 1 suppliers throughout North America.
(source: Can-Eng)
Can-Eng Furnaces International Ltd., of Niagara Falls, Ontario, was chosen for this project because it has significant experience in the development of lightweight, thin-walled automotive structural components. Can-Eng provided the customer with a unique rapid-heating furnace system that offers significant reduction in floor space requirements, flexibility for processing a wide range of product sizes, and the flexible operating temperatures required for various stamped and formed products. The system will be fully integrated with flexible robotic handling and material handling automation.
Welcome to another episode of Heat Treat Radio, a periodic podcast where Heat Treat Radio host, Doug Glenn, discusses cutting-edge topics with industry-leading personalities. Below, you can either listen to the podcast by clicking on the audio play button, or you can read an edited version of the transcript. To see a complete list of other Heat Treat Radio episodes, click here.
Audio: Heat Treat Modeling With Justin Sims
In this conversation, Heat Treat Radio host, Doug Glenn, interviews Justin Sims of DANTE Solutions about heat treat modeling. As the heat treat world moves farther way from mysterious black box processes, find out how the latest advances in heat treat simulation software can help your company model specific processes and materials in advance, leading to less guesswork and more profit.
Click the play button below to listen.
Transcript: Heat Treat Modeling With Justin Sims
The following transcript has been edited for your reading enjoyment.
We're going to talk to Justin Sims, lead engineer at DANTE Solutions, Inc., about heat treat modeling. It's a pretty interesting topic. With all the advances and sensors and computing power, the heat treat world is moving further and further away from the mysterious black box processes of yesteryear and is allowing companies to model specific processes and specific materials in advance so that there is less guesswork and more profit. DANTE provides the means by which companies can accurately predict what is going to happen to their part during the heat treat process.
DG: Justin is not only the lead engineer at DANTE Solutions, he is also the author of an article that just appeared in the March 2020 issue of Heat Treat Today and the title of the article wasProcess Innovation To Reduce Distortion During Gas Quenching. It was a pretty interesting article, something worth reading if you haven't already. It has to do with DANTE controlled gas quench.
JS: I got my bachelors in mechanical engineering degree from Cleveland State. I graduated back in 2015. I actually started interning at DANTE in 2014 and went full-time in 2016. I've been the lead/principal engineer at DANTE with mainly responsibilities of managing projects, training our DANTE users, and offering support to our DANTE users. I helped develop our patent-pending DANTE controlled gas quenching process, which you had just mentioned, and then also a little bit of IT, marketing, sales, and shipping. Being a smaller company, we can kind of do it all.
Fig. 1: Bevel gear axial distortion comparison for an oil quench, high pressure gas quench, and a DANTE Controlled Gas Quench
DG: Tell us briefly about DANTE.
JS: DANTE Solutions is an engineering consulting and software company. We offer consulting services as well as licensing our software. We mainly focus on the aerospace industry, the auto industry quite a bit as well, and we've been starting to get into the mining and energy sectors also. As I said, we are a smaller company. There are six of us right now. Two to three guys mainly focus on the software side, and the rest of us focus on more of the training, the support, and the consulting side of the business.
DG: DANTE is located near Cleveland, OH, and Lynn Ferguson, who has been in the heat treat industry for many, many years, was one of the founders. Let's talk about the genesis of the software. Would you say the software is the core product that DANTE Solutions offers?
JS: Yes, it is. We mainly stay in consulting to stay current and to give those users who don't have the capability to run our software (either they don't have the hardware or they don't have the analysts to be able to do such a thing), so we still offer our consulting services for them. But mainly, software is our main line of business. DANTE was actually formed back in 1982 as Deformation Control Technology, Inc., and we changed our name in 2014 to actually reflect more of the software side, so that's when we changed to DANTE Solutions, Inc.
The project itself that DANTE came out of actually started in 1994 and 1995. It was a collaboration between Ford, GM, Eaton Corp. and then four national labs--I believe they were Los Alamos, Sandia, Oak Ridge, and Lawrence Livermore--and then us as Deformation Control Technology. The whole project came out because those large automakers were claiming millions of dollars of lost scrap from distortion. It was starting to become a major issue and they wanted a way to be able to model the process and be able to optimize the process a little bit better. After that project ended, DANTE somehow ended up with the software, which has worked out well, as we've been able to commercialize it and we've been updating all the material models and the material database for the last 20 years. It's actually come quite a long way.
DG: How did you segue over from auto industry into aerospace?
JS: It just happens that the aerospace components cost a whole lot more than the auto industry components. It was a natural fit once they realized that this software was viable and could do what they needed it to do. And aerospace seems to be more receptive to modeling because their parts are so expensive.
DG: Let's try to put a little flesh on the bones here. For a manufacturer who has their own in-house heat treat for aerospace, automotive, energy or whatever, what makes this software attractive? What makes it viable? Why would someone want it, and why and how do they use it?
JS: Let's start with viability. The first thing is that it is easy to use. DANTE is a set of material routines that link with Abaqus or Ansys finite element solvers. These are solvers that engineers and analysts in the industry already know pretty well, so there is not a lot of learning of new software. DANTE is just a material model, so all you're really responsible for is the material name and what microstructural phases you're starting with. Then we have the ability to modify a few of our control parameters, activating different models; we've introduced stress relaxation, carbon separation, carbide dissolution, and all these different models that you can activate. But the biggest thing that trips people up . . . [is] understanding your process. We like to work with people a lot on trying to help them understand what type of thermal behavior their processes are actually imparting on components. We've done a lot of work with setting up their essentially quench probes and be able to turn around and be able to take that back to heat transfer coefficients that get put into the model. As far as DANTE is concerned, it is fairly easy to use.
We've also developed what they're calling ACT (Ansys Customization Toolkit). It is essentially a series of buttons where you would click on these buttons, fill out information, and then essentially run your models. Abaqus, for the new version of DANTE, we've also developed a plug-in that essentially does the same thing. So DANTE has become very point-and-click. In this world, I think people like that simplicity.
Fig. 2: Axial distortion of a press quenched bevel gear
The next big one would be the accuracy that everybody is concerned about. Our accuracy is due to the models that we use and the algorithms that we employ. There are two types of accuracy. I've touched on the boundary condition accuracy, and that is how your process behaves thermally. That accuracy can be tough to get. It's very doable and we've helped people achieve some really amazing accuracy. The relationship I like to use here is people know static loading models and a lot of engineers have run static loading models. The loads that you put on these static models are going to determine what deflections you get. If your load is not correct, then your deflection will not be correct. In heat treat modeling, the thermal boundary condition is your load. The more accurate your heat transfer coefficient can be, the more accurate your results are. But, with that being said, you can still gain a lot of valuable information from being close enough. We'll talk a little bit about that with the uses and whatnot.
The first important model type that we use is the mechanical model. We use a multiphase internal state variable model. A conventional plasticity model considers stress as a function of strain only, where the internal state variable model actually accounts for the history of deformation by relating the stress to dislocation density. It actually accounts for the history of deformation, which is very important as the steel goes through all the stress reversals that it does going through the process. Our mechanical model defines each phase, so austinite, pearlite, ferrite, bainites martensite, tempered martensite, all of them, as a function of carbon, temperature, strain and strain rate. It also accounts for the trip phenomenon.
For our phase transformation model, we like to use analytical models instead of TTT CCT diagrams, and we do this because you don't get any transformation strain information out of the diagram. So you have no idea how much it is deforming. In order to figure that out, we like to use dilatometry tests to fit to our analytical models. We also account for carbide growth and dissolution during carburizing, which is becoming a major point of interest due to the high alloy content of some of these steels that they're now trying to carburize.
DG: Let's talk a bit more about where manufacturers, who have their own in-house heat treat, might use DANTE's software tool.
JS: One of the big things we like to use it for is what we call sensitivity analysis. This would be, "what happens if my normal process has a little bit of variation?" Or, "what happens if my process parameters change a little bit?" We've also worked into the model now normal material variation. So if your alloy content is a little on the high side, how would the material behave? If it's a little on the low side, how will it behave? [This] is a big deal. One example would be, "I just designed a new part and I want to make sure that it behaves given the range that I know my process can vary." All processes will vary. This is no way to make the process exactly the same every time. Also, in the sensitivity, you can ask the question, “What process variable is a distortion or stress most sensitive to?" By finding out what process variables cause the most sensitivity, then those are the process variables you really need to pay attention to during processing, then the other ones you can just make sure they're in range and leave them alone.
Development and design are two of the big ones that we're trying to get out there that this software can be used for. Everybody knows that it can be used for troubleshooting. Once something goes wrong, yes, sure the software is great and we help figure out a problem; but why not find the problem before it ever even happens? We've been trying to get people to use it for development of new carburizing and nitriding schedules as well as new recipe and design, and even novel processes. You had mentioned our DANTE controlled gas quench. That actually was conceived through all the modeling that we do and watching the response of the material and saying, “Wait a second. If we can control the martensite transformation rate, we can really control the distortion, so let's see if we can do this.” Things like that can come out of the software. Design as well, of optimizing shapes for quench. You can even do quench to fit, which is, "I know my part distorts this much, so let me machine it distorted and then it will fall into shape." Optimizing processes. All of that can be done through design development, and you can find these problems before they ever happen.
Another really big one that I like, and Lynn, our owner, is really keen on this one, is the understanding of your process. When you start to set up these models, you have to ask a lot of questions about your process. What is the HTC of my process, which relates back to agitation in the tanks, part racking, flow directions? You really need to know times and temperatures of every step in your process. So not just the heat to quench, but what about all those transfers in between? All of that needs to be done. So you end up asking a lot of questions like that.
The other one that I always like to say is that the heat treat software removes the black box. In the past, you know what goes in and you know what comes out, but what happens in the middle is kind of a mystery. The software helps you figure out what exactly goes on during your process. It can be very eye-opening.
Fig. 3: Minimum Principal stress of a carburized and oil quenched spur gear
DG: I've talked with James Jan and Andrew Martin over at AVL, and we talked about a variety of ways they use some of their software, and they mentioned that they work with you guys as well, and they were talking about not even just like a quench agitation, flow direction, and things of that sort, but part orientation as it goes into a quench. I assume that would be something also that you guys would be able to help analyze, right? Which way to even put the part into the quench?
JS: Sure, sure. And we've done that. The one that comes to mind is a long landing gear. This landing gear was about 3 meters in length, and we looked at even slight angles going into the quench tank can have serious consequences on the distortion. That is definitely something that we've looked at in the past.
DG: Just that orientation would help, but maybe eliminate vapor stage, or whatever, I assume? Or pockets?
JS: Right. And even beyond that, it sets up thermal gradients in different locations of the part. So now instead of cooling one section faster, you're cooling it a little slower and that kind of thing. That also relates back to actual vapor stages and how bubbles get trapped. But that goes back to defining boundary conditions, which is where software like AVL's FIRE can really be helpful in understanding flow patterns. There is a beneficial relationship there.
DG: There are a host of different materials that people are using. How broad is the database, as far as the different types of materials, that you can analyze and model?
JS: That is a good question. We have a lot of low alloy, medium alloy, and carburizing grades of steel, the 1000 series, the 8600 series, 9300 series, those types of materials. We've also worked with some of the high alloy aerospace grades like C64 and the Pyrowear 53 and that sort of thing. But right now, it's all steel. There is a lot of talk about being able to do aluminum. We get that question a lot.
DG: I was wondering about that specifically- aluminum and/or of course, when we talk aerospace, we're talking titanium. So titanium is not on the table at the moment?
JS: It is, but it isn't. The interesting thing is that there is a phenomena precipitation hardening that goes on in aluminum and titanium. But it also goes on in these high alloy steels. It is a secondary hardening mechanism. We've been working on that and we feel that once we can handle secondary hardening in steel, then the jump to aluminum and titanium should be pretty straightforward.
DG: So to recap, for those of us who are not as well-versed in the product as you are, basically you've got a simulation software that takes into account the material that is being used, also the thermal process (the recipe), which would include both a controlled heat up and potentially a controlled quench. Is that a reasonable way to describe it in a very broad way?
JS: Yes. And also, even the steps before that, like carburizing. If the part is carburized, you would carburize it first. Or nitriding; we've just introduced those models. You can literally do the entire process. And it's not just quenching either. We've done martempering, austempering, normalizing, all of these things. Most all normal thermal processing, DANTE can handle.
DG: The last question I want to ask is, Who is the ideal person/company that would really find the product/service that you're providing useful? I know you mentioned aerospace and automotive, but can we be more specific than that? Where are you finding the most success?
Fig. 4: Displacement versus temperature curves showing the shift in martensite start temperature for 3 carbon levels
JS: That's a tough question. Generally, everybody that has used our software has found real benefit in it. We've tried to get testimonials from a lot of folks, but this can be difficult because of their companies. But from Cummins, we've gotten good responses and also from GM we've gotten good responses. One of them has used it to actually introduce new material and replace legacy material that is now saving them quite a bit of money. GM has used it to look at process design and optimization. But I would say mainly the people that are going to benefit the most are the folks that have an analyst to be able to do the simulation almost on a daily basis. It's one of those things where the more you do, the more you see and the more you understand what is happening. But really anybody that does heat treatment can benefit from understanding what's going on in their process.
DG: You mentioned Cummins, and I'm looking at your website, and I just want to read a paragraph:
DANTE heat treat simulation software has been a great boon to Cummins. Since we've started using their software, we have gone through several projects that have increased our understanding of heat treatment and some of which have saved us production costs. One example was enabling us to gain the leverage needed to make a material and process change on a legacy product that is now saving us at least 25% on material costs. The team at DANTE Solutions has always been very accommodating and is very quick to give assistance and feedback whenever troubles arise, even when the troubles are caused by other parts of the simulation and not DANTE itself. I look forward to working with DANTE team in the coming years as we expand our list of engineers who use this software. -- Brian W. at Cummins
So that leads me to one other question. When a person interacts with you, are they buying software as a service? Is it cloud-based or is it something that they purchase a license for one computer, one user? How does it work?
JS: There are a couple of different ways. They can lease it annually or they can essentially buy the software and lease a license annually. The software can go either on their computer or it can go on a server at their company. We also have options for corporations where you can essentially get software at different locations. We have a lot of options and we can work with customers if they [have] unique needs. That's one of the benefits of being a smaller company, we're pretty flexible like that.
DG: DANTE's mission statement from their website has a nice ring to it: “DANTE Solutions is determined to promote the use of simulation in the heat treat industry. From design to troubleshooting, DANTE Solutions believes everyone can benefit from a little simulation in their life.”
If you'd like to get in touch with Justin Sims at DANTE, please email me, Doug Glenn, directly at doug@heattreattoday.com and I'll put you in touch with Justin.
Doug Glenn, Heat Treat Today publisher and Heat Treat Radio host.
To find other Heat Treat Radio episodes, go to www.heattreattoday.com/radio and look in the list of Heat Treat Radio episodes listed.
A North American steel supplier announced today that it has begun operating its continuous galvanizing line, which will produce hot-dip galvanized sheet steel for the automotive market. Nucor-JFE Steel Mexico, located in Silao, Guanajuato in central Mexico, has begun trial production and will move towards full-scale sales and production once customer approvals have been obtained.
Leon J. Topalian, president and CEO, Nucor Corporation
“We are excited to expand our presence in Mexico and to use our local sales network to increase our sales into this important automotive market,” said Leon Topalian, President and CEO of Nucor. “We are proud to partner with JFE Steel Corporation of Japan and to benefit from their experience as a premier supplier of high-quality products to the automotive industry.”
The hot-dip galvanized sheet steel production facility has a production capacity of 400,000 tons annually. It can produce sheet thickness from 0.4 mm to 2.6 mm and widths of 800 mm to 1,850 mm. Nucor and JFE will each supply an equal amount of substrate to be processed at the new facility.
Multi-material design aiming at application-optimized technical components has been gaining importance over the last several years. In this context, combining steel and aluminum offers an effective solution for implementation of lightweight concepts due to its high strength-to-weight ratio. Due to the dissimilar material properties of steel and aluminum, the process design for bi-metal forming is very challenging and requires a process-specific heating strategy, the development of which is the focus of this paper, originally presented at IFHTSE TPIM 18 in Spartanburg, South Carolina. The current study involves the potential for creating bi-metal bearing bushings consisting of steel 20MnCr5 and aluminum AA-6082 by closed-die forging.
This article by Bernd-Arno Behrens, Robert Goldstein, and Anna Chugreeva originally appeared in Heat Treat Today’sJune 2019 Automotive Print Issue.
Introduction
The world-wide competition in the transportation industry has awakened in manufacturers a growing interest in developing cost-effective and environment-friendly technologies reducing fuel consumption. This trend results in increasing demands on technical components and requires production of high-performance components with advanced functionality and weight reduction. Conventional materials cannot satisfy all these requirements due to material-specific limitations.
Multi-material designs afford the opportunity to place the appropriate material at the appropriate location with regard to individual operational conditions. When combining the benefits of different materials in a single component, it is possible to create application-optimized parts with a significant weight reduction while maintaining high durability and performance.
In this context, combinations of dissimilar materials, such as steel and aluminum, are becoming increasingly important for research and development. However, the forming of steel-aluminum components is rather challenging due to the various thermo-physical properties of each material. Most challenging is the fact that the forming temperature of steel significantly exceeds the melting point of aluminum. In order to achieve correct material flow and complete die filling, specific heating strategies are necessary to create the appropriate temperature gradients between different regions in the component.
The current study introduces a method to produce bi-metal bearing bushings by closed-die forging. The overarching goal was to examine the feasibility of this approach for bi-metal forming and to establish the effect of the thermomechanical processing during heating and forming on the bond quality. To study the process, bi-metal workpieces joined by shrink fitting were used. In order to define the temperature distribution appropriated for the subsequent forming, the induction heating process was investigated by modeling and experimentation. Besides the achieved temperature gradients used for the forging experiments, forged bearing bushings, and results regarding material flow, microstructure and the bonding zone are demonstrated. Additional considerations are given on how to further improve the process and achieve production capabilities.
State of the Art
At the industrial scale, multi-material machine components (i.e. brake discs, hydraulic cylinder rods, valves, shafts, etc.) are commonly fabricated by joining two individual components that are already given their near-final or final form. An alternative solution is represented by the bulk metal forming of multi-material components, where forming and joining can be combined within a single-process step.
In recent years, joining by plastic forming was studied in several research works. Plancak et al. performed analytical and experimental compression tests on co-axial bi-metallic workpieces consisting of two different steel materials (C15E/C45E) in order to investigate load characteristics during the forming depending on different upset ratios [1]. Sun et al. investigated the metallurgical bonding process of bimetallic hot deformation and influence of process parameter on the diffusion behavior of different elements [2]. The compression tests were conducted under isothermal conditions using a serially arranged combination of a carbon steel Q235 and a stainless steel 316L.
The study showed that element diffusion distance in the interface zone increases with effective strain, temperature, and time during both forming and holding stages to different degrees. Behrens et al. studied compound forming of bi-material shafts by indirect impact extrusion of different steel combinations such as a structural steel S355J and a heat-treatable steel 42MoCr4 [3]. Tensile tests of bi-material specimens showed that a failure is located outside of the joining zone, which indicates a good bonding quality between materials after forming. The results were transferred to the precision forging of bi-metal spur gears with different diameters of core material and various thickness of wear-resistant ring materials.
Politis, et al. presented compound forging of gears made of dissimilar material combinations utilizing steel or copper on the outer diameter and aluminum, copper, or lead for the inner core [4, 5]. Äyer used a numerical and experimental approach for upsetting bi-metallic hollow cylinders made of copper and aluminum in order to investigate the material flow behavior during the forming [6]. A similar research work was carried out by Misirli et al. on bi-metal workpieces consisting of a steel outer ring (AISI 102) and brass or copper inner cylinder [7]. Kong et al. investigated manufacturing steel-aluminum compounds (AISI 316L/6063) by forge welding with various process parameters including temperature, amount of diameter, and forging speed. It was established that the forming temperature has the most decisive influence on the resulting quality and the tensile strength of the joint [8].
Wohletz and Groche elaborated a joining process by combined forward and cup extrusion and compared the joining of steel C15 and aluminum AW 6082 T6 at ambient and elevated temperatures [9]. It could be stated that while elevated forming temperatures have a positive impact on the final bonding quality, it is negatively affected by the emerging oxide scale that grows with increasing temperature. Kosch and Behrens investigated the compound forging of hybrid workpieces in the context of non-uniform temperature distribution between steel and aluminum raw parts and its influence on the emerging intermetallic phases [10]. Chavdar, Goldstein et al. used tailored heating strategies for hot forging and hot hydroforging of aluminum workpieces fully encapsulated within a steel shell, where the aluminum core was formed in a semi-solid or completely molten state [11, 12].
Initial and Final Geometries
Figure 1: Design of steel-aluminum workpiece (a) and bearing bushing (b)
The current study deals with manufacturing of a bearing bushing consisting of steel 20MnCr5 on the internal diameter and aluminum AA-6082 on the external diameter. The inner rolling surface is exposed to high stresses due to bearing balls and requires an application of high performance and wear resistant material such as steel. Removed from the high-stressed regions, lightweight materials with high toughness, ductility, and breaking resistance such as aluminum can be used for reducing the total weight of the part. The coaxially arranged bi-metal workpieces were designed in accordance with the stress conditions operating in the final parts. In this study, two concentric cylinders were joined together by shrink fitting and subsequently formed to the final geometry. The models of investigated bi-metal workpieces and bearing bushings are presented in Fig. 1.
Induction Heating Strategy
In order to achieve sufficient formability, the bi-metal workpieces have to be heated up to material-specific forming temperatures. For this purpose, a tailored heating strategy with radially inhomogeneous temperature distribution is required. For forming without cracks or other material defects, the warm or hot working temperature range (greater than 1292°F [700°C]) should be obtained in steel. At the same time, the aluminum temperature is limited to the melting onset (solidus temperature) at approximately 1076°F (580°C). Reaching required temperature gradient within the bi-material workpieces is possible using induction heating.
Induction heating is a volumetric heating method where power is controllable along the surface and in the depth of the workpiece. With the appropriate coil design and proper selection of frequency, it is possible to deposit electrical energy into the steel component with almost no direct inductive heating of the aluminum component. Using induction heating, the heating process can be tailored to achieve different temperature gradients in the composite structure to optimize the forming process [13].
Figure 2: Induction heating concept for hollow bi-metal cylinders (a) and induction coil with magnetic flux controller (b)
According to the geometry shown in Figure 1, an induction heating concept with a water-cooled inner induction coil and magnetic flux controller was designed (Fig. 2). With this construction, the eddy currents are primarily induced in the inner periphery of the workpiece, which leads to a more pronounced heating of the inner steel ring compared with the aluminum. The heating of the aluminum outer ring is due to conductive heat transfer from steel to aluminum.
For experimental heating tests, a middle-frequency generator Huettinger TruHeat MF 3040 with a frequency range between 5 and 30 kHz and a maximum output power of 40 kW was used. The induction coil was connected to the capacitor box with total capacity of 47.1 μF included in an oscillating circuit.
Figure 3: Position of measurement points during the heating tests
The heating process was controlled with set value presetting via percentage of the maximum voltage (300 V). For achieving the largest possible temperature difference between steel and aluminum in a short time, all tests were carried out at 100% voltage with various heating times. The maximal operating frequency was approximately 16.5 kHz. During the heating tests, time-temperature curves were recorded for the reference points in the middle of steel and aluminum rings, which are shown schematically in Fig. 3. For the measurements, mineral insulated NiCr-Ni thermocouples (Type K) with an Ø 1.5 mm stainless steel sheath were used.
In order to complement the experimental temperature values and to predict radial temperature distribution after the heating and transportation time, the induction heating process was modeled using the electromagnetic and thermal analysis software ELTATM. The main challenge of bi-metal heating modeling is to identify the thermal contact properties between steel and aluminum, which have a significant effect on the resulting temperature gradients. For this reason, the simulated thermal behavior should be matched to the experimental data [11, 12].
Figure 4: Time-temperature curves obtained by experimental test and simulation with ideal thermal contact between steel and aluminum (heating time 14 s)
In Fig. 4, the experimental temperature curves for the heating time of 14 s are compared with simulated results under ideal thermal contact condition between steel and aluminum. In both cases, the curves equalize at the same temperature, which means that the heating was performed based on the same total energy input. More efficient contact provides for faster equalization of temperatures, which can be explained by higher heat conduction from steel to aluminum. Under real-life conditions, the connection in bi-metal workpieces without metallurgical bonding is not perfect. This results in significantly less heat transfer and slower heating of the aluminum ring. Therefore, the temperature equalization takes a longer time in workpieces produced by shrink fitting. In this case, a higher temperature gradient between steel and aluminum is favorable for the subsequent forming process.
It should be taken into account that the contact characteristics between steel and aluminum are not constant over the heating time. Due to different thermal expansion of steel and aluminum, the gap between the materials grows with increasing temperatures. This behavior can be proven by experimental investigations. Fig. 5a shows the temperature curves with various heating time (from 10 up to 14 s). The resulting absolute temperatures and temperature gradients between steel and aluminum are different, but the initial heating process is reproducible for all of the tests.
Figure 5: Time-temperature curves with various heating time from experimental measurements (a) and magnified view of the interface with changing thermal behavior of steel (b)
In Fig. 5b, it can be seen that the temperature curves for steel have a slight bend at the same point, when the steel temperature (approximately 752°F [400°C]) is about two times higher than the aluminum temperature (approximately 392°F [200°C]). Higher heating rates of steel after this point can be explained by lower thermal conduction from steel to aluminum due to increasing gap size between steel and aluminum parts. This effect should be considered by modeling of the heating process.
In order to reproduce this phenomenon in heating simulation, a thin layer with temperature dependent conduction properties was integrated in bi-metal workpieces between steel and aluminum [11, 12]. The temperature curves received with the validated model are shown in Fig. 6. They agree with the experimentally measured temperatures. The slight deviation at the beginning and the end of the heating process can be explained by thermal lag of the thermocouples because of relatively greater diameter of their steel sheath.
Forging Process
Figure 6: Time-temperature curves obtained by experimental test and simulation with variable power and conductivity gap (heating time 14 s)
Forging processes represent a promising method for forming bi-metals due to several benefits, such as outstanding material properties, uninterrupted grain flow, and homogeneous structure. Moreover, forging at elevated temperatures enables reaching high strains and forming complex geometries in a single stroke. Additionally, thermal and mechanical influence during the forging can lead to improving local mechanical properties and the quality of the resulting joining zone.
For manufacturing bearing bushings from bi-metal hollow workpieces, a single-step forging process was designed. The forming is performed in a closed-die forging system, which is presented in Fig. 7. Within the forging stage, the material is formed by two active tool components—a punch and a closure plate. While the upper punch gives the inner shape of the bushing, the closure plate attached to the moving frame by a set of disc springs ensures the final height of the forgings. At the end of the forming process, the forged bushing is automatically detached from the upper punch with the force stored in the disk spring stacks. A hollow ejector system then removes the final bearing bushings from the forging die.
Figure 7: Forming tool system for closed-die forging of bearing bushings
Before the forming process, the warm workpieces are automatically transferred from the induction heating unit to the forming tool by means of a programmable robot arm to ensure high reproducibility and to limit heat exchange during transportation. The transportation time was limited to 6 s for all of the forging tests. After the forging, the final parts are cooled down by air.
Results and Discussion Temperature Distribution
Figure 8: Radial temperature distribution in steel-aluminum workpieces after heating and transportation time
The maximum heating time during the experimental investigations was limited to 14 s. With increasing heating time, the temperature of steel and aluminum equalizes above the solidus temperature, which leads to the partial melting of aluminum. Fig. 8 represents the temperature evolution for three heating strategies (a, b, and c) with various heating times. The diagrams show the radial temperature distribution directly after heating and transportation time. The temperature profiles after the transportation corresponding with the forming temperature are of great importance for the following forming process. In strategy a (Fig. 8, left), the steel shows the lowest temperature and thus will have reduced formability compared with other heating strategies. At the same time, the heating strategy b (Fig. 8, middle) leads to the largest temperature gradient between the steel and aluminum and thus is the most suitable for subsequent forging. The final temperature of steel is between 1292-1382°F (700-750°C) and the temperature of aluminum is about 806°F (430°C). With heating strategy c (Fig. 8, right), similar steel temperature has been achieved, although the entire heating phase was longer in this case. With this strategy, the aluminum is heated to a higher temperature of approximately 896°F (480°C) after transportation due to its high thermal conductivity, and thus a lower temperature gradient compared with strategy b can be achieved.
Forged Bearing Bushings
Based on conducted investigations, heating strategy b with heating time of 13s and transportation time of 6s has been primarily used for the subsequent forming tests. The bearing bushing forged using the selected heating strategy is presented in Fig. 9.
Figure 9: Material distribution in bi-metal bearing bushings after forging
Due to the lower flow stress, aluminum flows over the steel and forms an undercut in the upper part of the bearing bushing. The steel in the upper part undergoes a high radial expansion leading to a wall thickness reduction from 6 to 5 mm. In contrast to this, the wall thickness of the steel part is increased up to 7 mm in the bottom area, possibly due to axial up-setting. As observed in Fig. 9, the bearing bushing exhibits a sufficient macroscopic form fit between the steel and aluminum part. For detailed characterization of bonding quality, the specimens extracted from the forged bearing bushings were metallographically investigated. The metallographic cuts with resulting joining zone are presented in Fig. 10.
In general, two zones with different bond quality can be indicated as shown in Fig. 9 (green, red). In the upper area, a form- and force-closed joint has been achieved (Fig. 10a, left). In addition, a wavy topography from the finishing process can be observed in a higher magnification (Fig. 10a, right). In the bottom area, an undesired separation was detected (Fig. 10b, left). Due to the similar topography of both materials in some areas of the interface zone, it can be assumed that the separation is partially caused by shrinkage during the cooling process. A maximal gap size of approximately 40 μm was measured (Fig. 10, right).
Figure 10: Cross-sectional micrographs of bi-metal parts after forging from upper (a) and bottom (b) component areas
Conclusions and Outlook
The presented work focuses on the issues occurring during the forming of bi-metal components. In this case, employed heating strategy becomes a key tool to control temperature distributions in the component, which are critical in efforts to achieve appropriate material flow during the forming process. In this context, a process for production of steel-aluminum bearing bushing, including the FE-aided development of a reliable inductive heating strategy, has been designed. The feasibility of the developed methods has been successfully validated with an experimental forging study. Metallurgical evaluations were conducted on the formed bi-metal components.
The metallurgical studies showed good bonding was achieved with both the form- and force-closed joint in the areas with high deformation. In the bottom area of the bearing bushing, where the material is less deformed, the resulting bond quality was poor. Thus, the forming process (e.g. punch geometry) or the heating strategy (higher temperature gradients by changing the input power) needs to be improved to ensure sufficient bonding over the entire joint zone.
Metallurgically bonded bi-metal blanks produced by coaxial lateral extrusion will be employed in further investigations. Thus, the materials will be joined prior to forming, which should have a further positive impact on the resulting joint quality. However, due to improved contact between the workpieces, higher power from the induction heating power supply would be beneficial in achieving the desired temperature gradients.
Acknowledgements
The results presented in this paper were obtained within the Collaborative Research Centre 1153 “Process chain to produce hybrid high-performance components by Tailored Forming” in subproject B2. The authors would like to thank the German Research Foundation (DFG) for the financial and organizational support of this project.
About the Authors
Bernd-Arno Behrens is the Director of the Institute of Forming Technology and Machines (IFUM), Leibniz Universitat Hannover, Germany. Robert Goldstein is the Director of Engineering with Fluxtrol, Inc. Anna Chugreeva is a Research Associate with the Institute of Forming Technology and Machines (IFUM), Leibniz Universitat Hannover, Germany. This article originally appeared in Heat TreatToday’sJune 2019 Automotive Print Issue and is published here with the authors’ permission.
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