Heat Treat Today publishes twelve print magazines annually and included in each is a letter from the publisher, Doug Glenn. This letter is from theOctober 2025 Ferrous & Nonferrous Heat Treatments/Mill Processing print edition.
Karen Gantzer, associate publisher, and I recently visited a manufacturing plant with an extensive, in-house heat treat operation. We don’t often visit captive heat treat operations even though the vast majority of our audience are, in fact, captive heat treaters — manufacturers with their own in-house heat treat capabilities.
The conversation we had with the two heat treat specialists that hosted us was wide-ranging and enlightening. One of the topics was the rationale used for purchasing new thermal processing equipment. They have two mesh belt furnaces and a small number of integral quench furnaces. All the furnaces came from the same supplier.
We asked them straight up, “Why did you buy from this supplier and not from others?” The answer was instructive not only for furnace manufacturers, but for all suppliers in the industry.
What Didn’t Matter
While the three points listed below had some influence, these were not as important to the captive as many furnace manufacturers believe:
Price. In fact, they outright told us that they did not buy the least expensive equipment. When company purchasing agents get involved, the decision-making process is complicated, but with this mid-sized company, the two key decision makers — the two guys who spent time with us — assured us that price was not the main driver behind their decision.
Equipment and controls features. Features were not unimportant, but they were not the driving factor. Each company that bid for the job had slightly different solutions making it difficult to compare features. Our hosts told us that several of the designs would have worked. They chose one, but it was not because they preferred that design over the others.
Quality. What exactly does “quality” mean? If ever there was an overused marketing word, “quality” is it! Quality was not a determining factor in the purchase of the heat treating equipment. All of the equipment was “quality” equipment… whatever that means.
What Mattered
There were two key factors that swayed the decision for this captive heat treater:
1. Responsiveness was the #1 reason why this captive heat treater chose this furnace manufacturer. Responsiveness took several forms. First, during the bidding process, the manufacturer set itself apart by being prompt and creative with design changes. They obviously listened to what the captive heat treater was saying and responded in a timely fashion with alterations/solutions that demonstrated understanding. Second, the ability to reach the “top guy” at the furnace manufacturer day or night brought a level of comfort that heavily tilted the scales in their favor. Both guys indicated that they had the president’s cell number in their phones — not on speed dial, because that’s not necessary — but in their phones just in case. And they’ve used that number multiple times with good results. Finally, the furnace manufacturer continues to be responsive even after the equipment has been installed and commissioned. If there is something new or different the guys want to do, they call the furnace manufacturer, speak to a real person, they are heard, and they get a response in a timely fashion.
2. Location was the second most important reason. Here’s why. First, the buyers were happy to be stimulating the U.S. economy and, more specifically, the regional economy. Second, they felt that a geographically close furnace manufacturer would be more capable of providing speedy service and parts if and when those items became necessary. Third, proximity allowed the buyer to inexpensively visit the furnace builder for manufacturing progress updates. And finally, a domestic manufacturer eliminated tariff concerns.
Obviously, a furnace manufacturer can’t be geographically close to all their clients. However, alleviating concerns about parts and service, accommodating on-site progress visits throughout the furnace manufacturing process, and manufacturing as much as possible in the U.S. would all be steps in the right direction.
All this to say, it is not so much the hard inputs like engineering, manufacturing, and finance that persuade customers to make a purchase. Rather, it is the softer inputs — the human elements — that help furnace buyers become comfortable, giving you a leg up on your competition. Comfort is an emotion… and as we all know and agree, “Everyone always buys emotionally all the time.”
Doug Glenn Publisher Heat TreatToday For more information: Contact Doug at doug@heattreattoday.com
Heat Treat Todaypublishes twelve print magazines a year and included in each is a letter from the editor. This letter is from the June 2025 Buyers Guideprint edition. In today’s letter,Karen Gantzer, editor-in-chief/associate publisher at Heat Treat Todayextols the virtue of continuous learning in the heat treatment industry.
May was a busy month. Much travel was part of the schedule — both business and pleasure. Our business trips, however, were filled with enjoyment in being with others and enrichment experienced through team building competitions and challenges to habits and disciplines. Upon reflection, it’s encouraging and empowering to be a lifelong learner.
As you know, heat treating involves heating and cooling metals under controlled conditions to enhance their strength, durability, and adaptability. Much like this process, learning as we age transforms our minds and perspectives, making us more resilient and capable of facing life’s challenges. Just as a metal alloy becomes tougher through repeated cycles of heating and cooling, our continued pursuit of knowledge — whether through new skills, experiences, or ideas — sharpens our minds and enriches our lives.
One of the opportunities to learn was through attending the Metal Treating Institute (MTI) Spring Meeting in San Juan, Puerto Rico. What a destination for a meeting — sunshine, ocean breezes, warm sand — someone had to go!
HTT Team at OX8 – Left to right: Aubrey Fort, Karen Gantzer, Doug Glenn, Ellen Porter, and Michelle Ritenour Source: OmedaBeach Olympics at MTI Spring Conference 2025 Source: MTI
It’s always a joy to catch up with friends from the industry and meet new folks as we listened to heat treaters share insights from their part of the thermal processing world. We were encouraged by coaches who shared tools to become better leaders and our competitive hunger was satisfied through Beach Olympics. All providing helpful takeaways to employ when we returned to the real world.
More Heat Treat Todaystaff attended the OX8 Conference in Chicago, hosted by Omeda, an audience engagement platform company that we work with. This event welcomed those in the publishing world. What a treat to meet others who work with words and whose goal is to increase audience engagement.
At Heat Treat Today, we believe people are happier and make better decisions when they are well informed. This conference focused on AI and how to responsibly use it along with other software tools to increase engagement for those with in-house heat treat operations. What a fun team building time! AI is a beast, but learning just a fraction of its capabilities with others was a blast.
Kenn Kington sharing how to become better leaders at MTI Spring Conference 2025 Source: MTIEllen Porter and Doug Glenn at OX8 Source: Omeda
How can you be a lifelong learner?
One learning opportunity is this month’s Heat Treat Today June issue — our annual Heat Treat Buyers Guide. Once a year we print the latest information about where you can find and learn more about heat treat equipment, products, services, and providers. It is a treasure trove of all things heat treat.
Additionally, you can continue to learn from the monthly installments of The Heat Treat Doctor (p.12), Controls Corner (p.117), and Combustion Corner (p.118), plus explore how to save money with ceramic fiber insulation by reading the conversation between Doug Glenn and Mark Rhoa of Chiz Bros (p.108).
Like heat treated materials that withstand stress, a mind that continues to learn grows more adaptable and robust, enabling us to contribute meaningfully to others. Learn all you can and enjoy the journey!
Karen Gantzer Editor in Chief/Associate Publisher Heat Treat Today
Have you decided to purchase batch or continuous furnace system equipment? Today's episode is part 2 of the Heat Treat Radio lunch & learn episode begun with Michael Mouilleseaux of Erie Steel. Preceding this episode were Part 1 (episode #102) and a Technical Tuesdaypiece, so listen to the history of these systems, equipment and processing differences, and maintenance concerns before jumping into this episode about capability and throughput.
Doug Glenn,Heat Treat Todaypublisher and Heat Treat Radio host; Karen Gantzer, associate publisher/editor-in-chief; and Bethany Leone, managing editor, join this Heat Treat Today lunch & learn.
Below, you can watch the video, listen to the podcast by clicking on the audio play button, or read an edited transcript.
The following transcript has been edited for your reading enjoyment.
An Example: Carburizing (00:52)
Michael Mouilleseaux: What we want to do here is just compare the same part, the same heat treating process, processed in a batch furnace and processed in a pusher.
Figure 1: Carburizing Load Example (Source: Erie Steel)
Here we’re just going to make an example:
Pusher Load Description (00:58)
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I’m going to take a fictious gear: it’s 2 ¾ inch in diameter, it’s got an inside diameter of an inch and a quarter, it’s an inch and a half tall, and it weighs 1.25 pounds. For our purposes here, we’re going to put these in a cast basket. For the furnace that we’re going to put them in, the basket size is 36 inches square — so, it’s 36 x 36. The height in this pusher furnace is going to be 24 inches; the inside dimensions of a 36-inch basket (actually it’s a 35-inch basket that sits on a 36-inch tray) is 32 ½ inches.
Michael Mouilleseaux General Manager at Erie Steel, Ltd. Sourced from the author
We’re going to say that this basket is 18 inches tall, so we’re going to get 7 layers of parts so that there’s approximately 1 inch between each layer of parts. This loading scheme gets us 700 pieces in a basket; it gets us 875 pounds net.
So the 36-inch basket that’s 18 inches tall and we’ve got 10 rows of 10 pieces, and we’ve got 7 layers of these things, so we have some room in between them. The reason for that is circulation of atmosphere and quenchant. This is what’s going to constitute the pusher load.
Batch Load Description (03:09)
Now, when we go to the batch load, we’re going to take four of these, because the batch furnace that we’re going to compare this to is going to be 36 inches wide and it’s going to be 72 inches long. We have two baskets on the bottom, 36, and then two of them is 72, and two on top. They’re 18 inches high, so 18 and 18 is 36 — a standard 36 x 72. It’s got 40 inches of height on it. I can take that 36 inches, put it on a 2 ½-inch tray and I can get it in and out of the furnace.
What is this four baskets? 2800 pieces in a load and 3500 pounds. That’s the difference. I’m comparing one basket, 700 pieces and 875 pounds and we’re going to compare that to what we would do if we ran a batch load, which is significantly more. It’s 2800 pieces and 3500 pounds.
What do we want to do with this?
Let’s say that we’re going to carburize this, and we want 50 thousandths case (total case depth of 0/050”). Now, I will show you very soon why we’ve chosen 50 thousandths case. Because at 1700°F (which is what we’re going to carburize at), the diffusion rate is 25 thousandths of an inch times the square root of time.
Now, I can do that math in my head. 25 thousandths times 2 is 50 thousandths. That means we need four hours. So, the part would have to be in the furnace for four hours, at temperature, carburizing, in order to achieve 50 thousandths case.
Figure 2: Batch IQ Carburizing Load (Source: Erie Steel)
Batch Furnace Time (04:59)
Let’s look at the next section. As we said, the furnace is 36 x 72 x 36 and we have 2800 pieces in the load. So, that is 1700°F. We’re going to say that there is 3500 pounds and there is probably another 800 or 900 pounds in fixturing so that’s about 4500 pounds. It’s very conservative; in a 36 x 72 furnace, you could probably get away with running 6,000 pounds. This is just a load that is well within the capability of that.
Furnace recovery is going to take two hours.
Doug Glenn: Meaning, it’s going to take you two hours to get up to temperature.
Mike Mouilleseaux: Until the entirety of the load is at 1700°F, that’s right. Inside, outside, top to bottom.
We’re going to carburize this at four hours, as we described previously; we calculated that and we need four hours to get our 50 thousandths case. Then we’re going to reduce the temperature in the furnace to 1550°F so that we can quench it.
So, we have two hours of furnace recovery, four hours at carburizing, two hours to reduce the temperature and attain a uniform 1550°F. That’s eight hours, and that’s what you would term an 8-hour furnace cycle.
We know that we have 2800 pieces in the load. In eight hours (2800 divided by 8) you’ve got 350 pieces/hour. That’s what the hourly productivity would be in this load.
We won’t talk about “what could we do.” There’s a lot of things that we could do. This is simply an example.
Pusher Furnace Time (07:05)
Now, in the pusher load, as previously described, it’s 36 x 36 and it’s 24 inches high. Now, we know that we have a basket that’s 18 inches high. Again, it’s going to sit on a 2-inch tray, so we’ve got 21 inches of the top of the basket that is going to fit in the furnace; there are going to be no issues with that whatsoever.
The controlling factor is that we want four hours at temperature. In the boost and diffuse, we have four positions. The furnace cycles once per hour.
We get one load size (700 pieces, 875 pounds) every hour. So, in this example (an 8-position, 36-square pusher) this process would yield 700 pieces an hour, and a batch furnace loaded as we described (same exact loading and number of pieces/basket) would yield 350 pieces/hour. In this scenario, the pusher furnace is going to produce twice the number of parts/hour that the batch would.
So, you would say, “Well, let’s just do that.” What you have to understand is that every hour, you are going to produce 700 pieces. If we went back and we looked at that description of what that pusher system looked like, you would see there are 23 positions in that. When I load a load, it’s going to be 23 hours before the first load comes out.
What we’re talking about is whether or not there were 700 pieces and 800 pounds, 23 of those[ET10][BL11] load.
The point would be, you either have to have enough of the same product or enough of similar product that can be processed to the same process to justify using something like this. Because if we want to change the cycle in the furnace. So, can we do that? The answer is absolutely, yes.
The preheat there, that stays at relatively the same temperature. The first zone in the furnace where we’re preheating the load, that temperature can be changed, as can the temperature in the boost diffuse and/or cycle time.
Figure 3: Pusher Furnace System (Source: Erie Steel)
So, in our example, we used an hour. What if you wanted 40 thousandths case and you’re going to be closer to 45 minutes or 50 minutes of time, how would you accomplish that? That can be done.
Typically, commercial heat treaters would come up with a strategy on how to cycle parts in and hold the furnace, or how many empties you would put in the furnace before you would change the furnace cycle.
Obviously, in the last two positions, where you’re reducing temperature, you could change the temperature in either the first two positions, where you’re preheating the load, or you could change the carburizing temperature, because when we’re dropping the temperature, it doesn’t have a material effect upon that.
Typically, in an in-house operation, you would not do that kind of thing, for a couple of reasons, not the least of which would be considering the type of people that you have operating these furnaces. They come in and out from other departments, and this is the kind of thing that you would want someone experientially understanding the instructions that you’ve given them. The furnace operator is not necessarily going to be the one to do it; this may be a pre-established methodology. You want them to execute that. But if you have somebody that is running a grinder and then they’re running a plating line and then they’re coming and working in the heat treat, that would not be the recipe for trying to make these kinds of changes.
As I described to you before, I worked in another life where we had 15 pushers. They were multiple-row pushers. We made 10,000 transfer cases a day. The furnace cycle on every furnace was established on the 1st of January, and on the 31st of December it was still running the same furnace cycle. You never changed what you were doing. The same parts went into the same furnaces and that’s how they were able to achieve the uniform results they were looking for.
Pusher Furnaces and Flexibility (12:45)
So, the longer the pusher furnace is, the less flexible it is.
In this example, you have eight. You know, there are pusher furnaces that have four positions. If you think about it, in a 4-position furnace, you could empty it out pretty quickly and change the cycle.
There are a lot of 6-position pusher furnaces in the commercial heat treating industry; that seems to be a good balance. The number of multiple-row pushers in the commercial industry, they’re fewer and far between. I’m not going to say they’re nonexistent, but enough of the same kind of product to justify that is difficult.
I think the bottom line here is, for companies that are having high variability, low quantity, low volume loads, generally speaking, your batch is going to be good because it’s very flexible, you can change quickly.
However, with a company like the one you were describing where there is low variability and very high volume, pushers are obviously going to make sense. But there is a whole spectrum in between there where you’re going to have to figure out which one makes more sense — whether you’re going to go with a batch or a continuous.
Mike Mouilleseaux: Possibly underappreciated is the aspect of distortion.
In that carburizing example, you’d say, “We have an alloy steel, we’re aiming for 50 thousandths case — what’s the variation within a load?” And I’m going to say that it is going to be less than 5 thousandths, less than 10%. From the top to the bottom, the inside to the outside, it’s going to be less than 5 thousandths. That same process, in the pusher furnace is going to be less than 3 thousandths.
That’s one aspect of the metallurgy. The other aspect is quenching.
Doug Glenn: 5 thousandths versus 3 thousandths — 3 thousandths is much more uniform, right?
Mike Mouilleseaux: Correct.
Doug Glenn: And that’s good because that way the entire load is more consistent (in the continuous unit, let’s say).
Mike Mouilleseaux: That is correct.
Then there is the consistency in quenching. In the batch furnace, you’re quenching 36 inches of the parts. If we had seven layers in the pusher, we have 14 layers of parts in the batch. What are the dynamics involved in that?
We have experience that the ID of a gear (it’s a splined gear) in a batch furnace, we were able to maintain less than 50 microns of distortion. There is a lot involved in that, that’s not for free; there’s a fair amount involved in that and it’s a sophisticated cycle, if you will. That same cycle in a pusher furnace, same case depth, similar quenching strategy, will give you less than half that amount of distortion.
To the heat treater, where we’re talking about the metallurgy of this, you’re going to think 5 thousandths or 3 thousandths is not a big deal.
To the end-user, that reduction in distortion all of a sudden starts paying a number of benefits. The amount of hard finishing that has to be done or honing or hard broaching or something of that nature suddenly becomes far more important.
Doug Glenn: Yes. That adds a lot of money to the total process, if you’ve got to do any of those post heat treat processes.
Mike Mouilleseaux: To a large extent, that is due to the fact that you have a smaller load. If you have a smaller load, you have less opportunity for variation — it’s not that it’s all of a sudden magic.
Doug Glenn: And for the people that don’t understand exactly what that means, think about a single basket that goes into a quench tank and four baskets, arranged two on top and two on bottom. The parts in the middle of that are going to be quenched more slowly because the quench is not hitting it as much.
So, the cooling rates on a stacked load are going to be substantially different than for a single basket, and that’s where distortion can happen.
Mike Mouilleseaux: There are a tremendous number of components that are running batch furnaces successfully. The transportation industry, medical, aerospace, military — are all examples. I’m simply pointing out the fact that there is an opportunity to do something but what we have to keep in mind is — how many of those somethings are there available?
The one thing you would not want to do is try to run four loads in a pusher furnace that could hold 10 because the conditions are not going to be consistent. The front end (the first load) has nothing in front of it so it’s heating at a different rate than the loads in the center, and the last load is cooling at a different rate than the loads that were in the center. That which I just described to you about the potential improvement in distortion, that would be negated in that circumstance.
Doug Glenn: If you’re running a continuous system at full bore and you’re running a batch system at full capacity, especially when you get to the quench, there are a lot of other variables you need to consider in the batch.
This is simply because of the load configuration, and the rates of cooling from the outer parts — top, bottom, sides, as opposed to the ones in the middle. Whereas with a single basket, you still have to worry about the parts on the outside as they’re going to cool quicker than the parts on the inside, but it’s less so, by a significant degree.
Mike Mouilleseaux: Something that I have learned — which is totally counterintuitive to everything that I was educated with and everything that I was ever told— we’d always thought that it was the parts in the top of the load where the oil had gone through and had an opportunity to vaporize and you weren’t getting the same uniform quench—those were the parts that you had the highest distortion.
Counterintuitively, it’s the parts in the bottom of the load that have the greatest degree of distortion. It has very little to do with vaporizing the oil and it has everything to do with laminar flow versus turbulent flow.
Doug Glenn: In the quench tank, is the oil being circulated up through the load?
Mike Mouilleseaux: Yes.
Doug Glenn: So, supposedly, the coolest oil is hitting the bottom first.
Mike Mouilleseaux: Yes.
Thoughts on the Future of Furnace Improvement (22:20)
Doug Glenn: What about the future on these things?
Mike Mouilleseaux: Where do we think this thing is going? Obviously, you’re going to continue to see incremental improvement in furnace hardware: in burners, in controllers, in insulation, in alloys. These things will be more robust; they’re going to last longer. If we looked at a furnace today and we looked at a furnace that was made 50 years ago, and we stood back a hundred yards, almost no one could tell what the difference was, and yet, it would perform demonstrably different. They are far more precise and accurate than ever.
For the process control systems, we’re going to see real-time analysis of process parameters. We don’t have that now. I think that machine learning is going to come into play, to optimize and predict issues and prevent catastrophic things.
In terms of atmosphere usage, if you’re running the same load, and you run it a number of times, the heating rate should be the same, and the amount of gas that you use to carburize that load should be exactly the same. But if you have a problem with atmosphere integrity — you got a door leak, you got a fan leak, or you got a water leak on a bearing — those things are going to change. Now, by the time it gets your attention, you could’ve dealt with that much sooner and prevented other things from happening.
"For the process control systems, we’re going to see real-time analysis of process parameters. We don’t have that now. I think that machine learning is going to come into play, to optimize and predict issues and prevent catastrophic things."
So, did it cause a problem with the part? By the time it causes a problem with the part, it’s really serious. The point is that there is something between when it initiated and when it’s really serious. With the right kind of analysis, that could be prevented. I think that that kind of thing is coming.
Motor outputs, transfer times — I see all of those things being incorporated into a very comprehensive system whereby you’re going to understand what’s happening with the process in real-time. If you make adjustments, you’re going to know why. Then you’re going to know where you need to go and look to fix it.
The other thing I see happening in the future is all about energy and greenhouse gases. Our Department of Energy has an industrial decarbonization roadmap today, and it’s being implemented, and we don’t even know it. One of the targets in this industrial decarburization roadmap is reduction in greenhouse gases: 85% by 2035, net zero by 2050.
So, what does that mean? I’ve listened to the symposiums that they have put on. There are three things that they’re looking for and one is energy efficiency. I’m going to say that we’ve been down that road and we’ve beat that dog already. Are there going to be other opportunities? Sure. It’s these incremental things, like burner efficiency. But there is no low hanging fruit in energy efficiency.
The other thing is going to be innovative use of hydrogen instead of natural gas because the CO₂ footprint of hydrogen is much lower than that of natural gas. If you look at how the majority of hydrogen is generated today, it’s generated from natural gas. How do you strip hydrogen out of there? You heat it up with natural gas or you heat it up with electricity. Hydrogen is four times the cost of natural gas as a heating source.
The other thing that they’re talking about is electrifying. It’s electrify, electrify, electrify. The electricity has to be generated by clean energy. So, does that mean that we run our furnaces when the wind is blowing or the sun is out, or we’re using peaker plants that are run off hydrogen, and the hydrogen is generated when the sun is shining or the wind is blowing, and we’re stripping out the natural gas?
From what I, personally, have seen with these things, these are absolutely noble goals. You could not disagree with them whatsoever. The way that they want to go about accomplishing it, and the timeline that they wish to accomplish that in, is unrealistic.
If you look at how the majority of hydrogen is generated today, it’s generated from natural gas. How do you strip hydrogen out of there? You heat it up with natural gas or you heat it up with electricity. Hydrogen is four times the cost of natural gas as a heating source.
Doug Glenn: Well, Michael, don’t even get me going on this! There are a lot of different things that are going on here but it’s good to hear you say this stuff. I agree with you on a lot of this stuff. They are noble goals; there is absolutely nothing wrong with electrifying.
Now, I do know some people — and even I would probably fall into the camp of one of those guys — that questions the premise behind the whole decarbonization movement. I mean, is CO₂ really not our friend? There’s that whole question. But, even if you grant that, I agree with you that the timeframe in which they’re wanting to do some of these things is, I think, fairly unrealistic.
It’s always good to know the reality of the world, whether you agree with it or not. It’s there, it’s happening, so you’ve got to go in with eyes wide open.
Safety Concerns (29:41)
Mike Mouilleseaux: The safety concerns on these are all very similar. You know, the MTI (Metal Treating Institute) has some pretty good safety courses on these things, and I think there are a lot of people who have taken advantage of that. The fact that it’s been formalized is much better.
When I grew up in this, it was something that you learned empirically, and making a mistake in learning it, although the learning situation is embedded in you, sometimes the cost of that is just too great, so that the probability of being hurt or burnt or causing damage to a facility, is just too great.
There are definitely things that need to be addressed with that, and there are some very basic things that need to be done.
Doug Glenn: Michael, thanks a lot. I appreciate your expertise in all these areas, you are a wealth of knowledge.
Michael Mouilleseaux is general manager atErie Steel LTD. Mike has been at Erie Steel in Toledo, OH since 2006 with previous metallurgical experience at New Process Gear in Syracuse, NY and as the Director of Technology in Marketing at FPM Heat Treating LLC in Elk Grove, IL. Having graduated from the University of Michigan with a degree in Metallurgical Engineering, Mike has proved his expertise in the field of heat treat, co-presenting at the 2019 Heat Treat show and currently serving on the Board of Trustees at the Metal Treating Institute.
Are you trying to figure out what heat treat equipment investments you need to make in-house and what is better being outsourced? This conversation marks the continuation of Lunch & Learn, aHeat TreatRadio podcast series where an expert in the industry breaks down a heat treat fundamental with Doug Glenn, publisher ofHeat TreatTodayand host of the podcast, and theHeat TreatTodayteam. This conversation with Dan Herring, The Heat Treat Doctor®, zeros in on heat treat ovens versus atmosphere furnaces.
Below, you can watch the video, listen to the podcast by clicking on the audio play button, or read an edited transcript.
The following transcript has been edited for your reading enjoyment.
Contact us with your Reader Feedback!
Doug Glenn: Welcome everybody. This is another Lunch & Learn event with the staff of Heat Treat Today and the illustrious Dan Herring, The Heat Treat Doctor®. Dan, we’re always very happy to spend some time with you.
We are here to learn a little bit about some basics about heat treat equipment, mostly ovens, air and atmosphere furnaces, and possibly vacuum furnaces.
Dan Herring: It’s always a pleasure, Doug, and hello everybody.
It is an exciting topic for me because I happen to love heat treat equipment. Let’s start with industrial ovens.
All About Ovens (01:42)
Years ago, industrial ovens were very easy to differentiate from furnaces. I’m going to give you my understanding of the differences between ovens and furnaces, and then talk a little bit about some general characteristics of all types of heat-treating equipment.
Ovens are typically designed for low-temperature operation. When I talk about low-temperature operation, years ago the definition was “under 1,000° F.” That definition has changed over the years. We now usually say either under 1250°F or under 1400°F. All of that being said, there are some ovens that run all the way up to 1750°F. But what we’re going to concentrate on are, what I call, “the classic temperature designations for ovens.”
Universal oven from Grieve Source: Grieve
First of all, ovens are typically rated at 500°F, 750°F, 1000°F, or 1250°F. If you see a heat treat operation that’s running — certainly under 1450°F — but even under 1250°F, it may be being done in either an oven or a furnace.
Let’s talk about some of the distinguishing characteristics of ovens, so everyone gets a feel for it.
Ovens always have a circulating fan. If you see a piece of equipment without a circulating fan, it can’t be an oven. At these low temperatures, the heat transfer — in other words, how you heat a part — is done with hot air or circulating hot air. So, ovens always have fans.
In most cases — and years ago in all cases, but today in most cases — ovens are metal lined. If you were to open the door of an oven and look in, and you see a metal-lined chamber, that would typically be an oven.
The fan and the type of insulation or lining that’s used is very characteristic for distinguishing features of ovens.
Today, however, there are ovens that use fiber insulation and even some ovens that have refractory-insulated firebricks, refractory in them. The lines are a little bit blurred, but typically you can distinguish them by the fact that they have fans and are metal lined.
Ovens come in either “batch” or “continuous” styles. If the workload inside the unit, the piece of equipment, is not moving, we call that a batch style furnace. If the workload is somehow being transferred through the unit, we call that a continuous furnace. Ovens and furnaces can be both batch and continuous.
Ovens and furnaces can both be either electrically heated or gas fired.
One of the distinguishing characteristics of ovens is that if they are gas fired, they are, what we call, “indirectly heated.” This means your burner, your combustion burner, is firing into a closed-ended tube, a radiant tube, as we call it, so that the products of combustion do not “intermix.” They do not create an atmosphere that’s used inside the oven. In fact, the majority of ovens run with an air atmosphere – that’s another distinguishing feature.
However, there are ovens that can run inert gases. Those ovens typically have continuously welded shells. Again, that’s an exception rather than a rule, but there are ovens of that type.
There are also vacuum ovens out there. We actually have an oven chamber on which we can pull a vacuum. They are less common than their cousins, the air ovens, but they are out there in industry.
We have the method of heating and type of movement of the hearth or movement of the load that typically is consistent between ovens and furnaces.
What I’d like to do is just show everybody a couple of pictures of some very typical, what I’m going to call, “batch ovens.”
Doug Glenn: Because ovens are typically low temperature, you’re able to have metal on the inside, right? If it was higher temperature, you’d start experiencing warping. Is that the primary reason why you tend to see metal in an oven and not in a furnace?
Dan Herring: That’s correct, Doug.
"Metal lined oven" Source: Dan Herring
The lining can be made of steel: it can be made of “aluminized’ steel,” it can be made of zinc-gripped steel (those are just coatings), it can be just steel, and they can be made of stainless steel (a 300 series stainless steel). That’s why you have the different temperature ratings and the different types of materials that this metal interior can be made from.
If you open the door of a metal-lined oven or an oven that had a metal lining, you would typically see what’s pictured here.
"Double door shelf oven" Source: Dan Herring
Ovens can be very small or they can be very, very large. What you’re seeing on the screen is a “double door shelf” oven.
It is very similar to your ovens at home. You open the door, there are shelves, and you can put trays on the various shelves. These can be small, to the point where, sometimes, they can sit on a benchtop. Sometimes they can be very, very large and be floor-mounted, as this one is.
This is an example of a batch oven, something that you would load, and the load stays stationary within the oven. Then, when you’re ready, you unload it.
Ovens can come in slightly larger sizes.
"A larger horizontal oven . . . . a fan system sitting at back" Source: Dan Herring
That’s a picture of a larger, horizontal oven. The door on this particular oven is closed shut, but you can see the fan system — that’s that yellow arrangement that’s sitting in back of this particular oven.
There is another style of oven.
"Walk in oven" Source: Dan Herring
We call this a “walk-in” oven — very creative, because you can walk into it. I’ve seen batch ovens that are very, very small and very, very large — ones that will fit on a benchtop and ones that are a hundred feet long.
You can see the heat source on the right hand side. Remember, whether it’s electrically heated with sheathed elements or if it’s gas-fired with, typically, an atmospheric-type burner, again, you have circulating air past either the electric elements or circulating air past the tube into which the burner is firing. You’re relying on convection — or moving hot air — to transfer that heat energy to your load.
These are just some different styles of different types of ovens, so everyone can see them. I don’t want to take too long, but I’ll show you another picture of one.
"Industrial oven . . . . typical oven in typical heat treat shop" Source: Dan Herring
This is an industrial oven. You can see the fan; it has a yellow safety cover on it. You can see the fan mounted on top, and this is a typical oven that you’d find at a typical heat treat shop.
Ovens have the characteristics that I pointed out. I’ll bring up one more picture which you might find interesting.
"Monorail conveyor oven . . . . with u-shaped radiant tubes" Source: Dan Herring
Since there are a variety of oven shapes and sizes, this happens to be a monorail conveyer oven. What you’re looking at is the inside of the oven. You’ll notice that in the ceiling there are hooks. The loads are actually placed on the hooks and sent through or pulled through the oven. This happens to be a gas-fired unit, and you can see that it has U-shaped radiant tubes into which you’re firing.
This oven is fiber-lined and not metallic-lined. You’ll also notice that because you see different colors of the tubes, this particular shot was taken and you destroyed the uniformity of temperature within the oven. Usually, they’re very tight.
Ovens are typically in the ±10°F range for temperature uniformity, sometimes in the ±5°F range.
Those are basically some pictures of ovens, whether they be batch or continuous, for everyone to see and think about, from that standpoint.
Q&A on Ovens (16:58)
Bethany Leone: What is the reason for the increase in temperature range for what classifies an oven?
Dan Herring: The main reason is the materials of construction have gotten better, so we’re able to withstand higher temperatures. But going to some of these temperature ratings, one of the things that heat treaters look at is if I have a process that runs at 1,000°F or 970°F (let’s take an aluminum heat treat example where a process is running at 970°F), I could run that in an oven rated at 1,000°F but I’m right at the upper limit of my temperature.
It's much better to buy an oven rated at 1250°F and then run a process such as 970°F where I have a margin of safety of the construction of the oven, so the oven will last longer.
However, industrial ovens tend to last forever. I’m the only person on this call old enough to have seen some of these ovens retired. It’s not unusual that an oven lasts 40 or 50, or sometimes 60 years.
Ovens are used in the heat treating industry for processes such as tempering, stress relief, for aluminum solution heat treatment, aluminum aging operations, and to do some precipitation hardening operations that run in these temperature ranges. Ovens are also commonly found in plating houses where you’re doing a hydrogen bake-out operation after plating. You also do various curing of epoxies and rubbers and things of this nature in ovens.
There are a variety of applications. Ovens are used also for drying of components. Ovens are used for drying of workloads, these days, prior to putting in your heat treating furnace. Many times, our washers are inefficient when it comes to drying. You take a wet load out of a washer and put it into a low-temperature oven, maybe running between 300°F and 750°F. Consequently, you both dry the washing solution off the parts and you even preheat the load prior to putting it into the furnace.
Heat Treat Today team enjoying a Lunch & Learn session
Doug Glenn: One of the things I’ve always distinguished ovens by is the term “panel construction” opposed to “beam construction.”
If you can imagine a sheet of metal, some insulation, and another sheet of metal – that’s a panel. It’s got enough insulation in it because the temperatures are not excessively high, but you really only need those three layers. You take those panels, you put them in a square or whatever, put a lid on it, put a bottom on it, and you basically have an oven, right?
Where furnaces are not typically constructed that way; they are constructed more where you have a support structure on the outside and then a heavy metal plate and then you build insulation on the inside of that. It doesn’t even need to have metal on the inside — it can be brick or another type of insulation.
Many people claim — and I’m sure there are some very strong ovens — that the oven construction is not as hardy, not as rugged. That’s one other minor distinction, but the main distinction is ovens tend to be lower temperature.
Dan Herring: Yes, that’s very correct, Doug. In panel-type construction, there is typically mineral wool insulation in between the two panel sheets; and it’s rated for obviously very low temperature.
There are, what we call, “light duty” and “heavy duty” ovens. Heavy duty ovens have that plate and support structure — those I-beams or channels — supporting the external structure.
Doug Glenn: You reminded me of something, Dan: We talk about ratings – oven ratings, furnace ratings, and that type of stuff. That’s pretty important and we haven’t really discussed that much. But if a furnace is rated at a certain temperature, you do not want to take that furnace beyond that temperature because there are real safety issues here.
There was one picture that Dan showed where you could see the metal interior, and there was like a gasket, if you will, around the whole opening. That gasket is only rated to go up so high in temperature. If you go over that temperature, you’d end up deteriorating that gasket, if you will. It could cause a fire, it could cause a leak, it could cause all kinds of issues. And that’s only one example.
One other one he mentioned was fans. There is almost always a fan in an oven, and if you take the temperature of that oven over its rated temperature, all of sudden the bearings in that fan start . . . well, who knows what’s going to happen.
You always want to know the rating of your oven and furnace, and don’t push the rating.
Dan Herring: Yes, if you exceed temperature in an oven, typically the fan starts to make a lot of noise and you know you’re in trouble. You only do that once. But those are excellent points, Doug, absolutely.
So, the world of ovens -- although it’s they’re an integral part of heat treating -- are a “beast unto themselves,” as I like to say. Construction is a factor, and other things.
All About Atmosphere Furnaces (24:50)
Furnaces, interestingly enough, can be rated both to very, very low temperatures all the way up to very, very high temperatures. In other words, you can see industrial furnaces running at 250° or 300°F or 500°F or 1000°F, — at typical temperatures that you would associate with oven construction — but you can also see furnaces running at 1700°F, 1800°F, 2400, 2500, 3200°F. There are some very interesting furnaces out there.
But furnaces, although they can run in air — and there are a number of furnaces that do — they typically run some type of either inert or combustible atmosphere inside them. Furnaces typically have an atmosphere, and they do not always have a fan. The rule is the higher you go up in temperature, the more any moving part inside your furnace becomes a maintenance issue. Many times, furnaces do not have fans in them.
They can be electrically heated. They could also be gas-fired. In this particular case, they can either be direct-fired or the burners are actually firing into the chamber; and the products of combustion become your atmosphere. They could be indirect-fired — like we discussed with ovens — into a radiant tube as a source of heat or energy.
Furnaces typically have plate construction. It’s typically continuous welded, they have channels or I-beams surrounding the structure to make it rigid, insulation is put on the inside. Traditionally it’s been insulating firebrick, but in what I’ll call recent years (20 years or so) fiber insulations have come about, and they perform very, very well.
Fiber insulations reduce the overall weight. They have advantages and disadvantages. A refractory-lined unit can have a great thermal mass due to the storage of heat inside the insulation, so when you put a cold load into a brick-lined furnace, the heat from the lining will help heat the load up quickly.
You don’t have quite the same heat storage in a fiber insulation. At the same time, when you go to cool a furnace, a fiber-lined furnace will cool very quickly as opposed to a refractory furnace which cools a lot slower.
Again, furnaces can be batch style, they can be continuous style, they can be fairly small in size. The smallest ones that I’ve seen, typically, are about the size of a loaf of bread. Conversely, you have furnaces that are so large you can drive several vehicles or other things inside of them.
A 14-foot long car bottom furnace Source: Solar Atmospheres of Western PA
As a result of that, what distinguishes them are typically their temperature rating and the fact that they use an atmosphere. Some of the atmospheres are: air, nitrogen, argon. I’ve seen them run endothermic gas and exothermic gas which are combustible atmospheres, or methanol or nitrogen-methanol which are also combustible atmospheres; they can run steam as an atmosphere. I’ve seen furnaces running sulfur dioxide or carbon monoxide or carbon dioxide as atmospheres. The type of atmosphere that is used in an industrial furnace can be quite varied.
We have several different furnace categories that typically are talked about: Batch style furnaces are configured as box furnaces. They are very similar in shape to the ovens that we looked at. Pit style furnaces are where you have a cylindrical furnace that actually is quite tall and fits down, usually, into a pit that’s dug in the factory floor.
You also have mechanized box furnaces. Those, typically, today, would be called integral quench furnaces or sometimes batch quench furnaces or “IQs.” There are belt style furnaces, gantry, tip-up, and car-bottom furnaces. There is a wide variety of batch style furnaces, all of which have the characteristic that once you put the load into the chamber, it sits there until it’s been processed and until it's time for you to remove it.
The exception is in an integral quench furnace. You push the load typically either directly into the heating chamber or into a quench vestibule and then into a heating chamber; you heat it in one chamber, you transfer it out, and you quench it into another chamber.
Those are some of the distinguishing features of batch style equipment. I’ve got a couple of pictures here that you might find interesting.
"A box furnace . . . . sometimes difficult by sight alone to tell an oven or box furnace" Source: Dan Herring
Here is a “box furnace.” You might say, “Oh, my gosh, it looks like an oven!” I see a fan on top, and it’s a box style. From the outside, it’s hard to tell whether it’s an oven or a furnace.
When you look at this unit, you might see that it’s made of plate construction. It would be difficult to tell if this unit were a heavy-duty oven or furnace unless you, of course, opened the door and looked inside. You would typically see either fiber insulation or insulating firebrick in these types of units.
Sometimes, just by sight alone, it’s very difficult to tell if it’s an oven or a furnace. But there are other telltale signs.
"A box furnace with retort" Source: Dan Herring
Now, this is a box furnace with a retort inside it. The workload is placed, in this case, into a metal container that’s physically moved on a dolly into the furnace itself. This is what we call a box furnace with a retort.
The process takes place inside the retort. You’ll notice that there’s a flow-meter panel there, of different gases, that are introduced directly into the retort. This style of furnace is very interesting because the furnace itself, outside the retort, is simply heated in air. It’s a relatively inexpensive construction. Also, when the time comes that the process is finished, usually you can remove the retort and introduce or put a second retort into the furnace while the first retort is cooling outside the furnace. It lends to increased production, from that standpoint.
But this is typically a box furnace; it looks like a big box. The shell does not have to be continuously welded because the process takes place inside the retort. You might be able to see, just past the dolly, there is a dark color and that is the blackish retort that’s actually being put in.
Doug Glenn: I think the reasoning of the retort is to protect the airtight atmosphere, right?
Dan Herring: That’s correct, Doug. The idea is the fact that it’s an effective use of your atmosphere.
The other thing you can do with a box furnace with a retort is you can pull a vacuum on the retort. As a result of this, you can actually have a “hot wall” vacuum furnace. That is what is defined as a hot wall vacuum.
The next type of atmosphere furnace we’re going to look at is pretty distinct or pretty unique: This is a pit style furnace.
"A pit style furnace . . . . there is probably 4X as much furnace below the floor" Source: Dan Herring
What you’re seeing here is only that portion of the furnace that is above the floor. There is probably four times as much furnace below the floor as there is above. OSHA has certain requirements: there must be 42 inches above the floor not to have a railing or a security system around the pit furnace, because you don’t want to accidentally trip and fall into a furnace at 1800°F. We don’t want to say, “Doug was a great guy, but the last time I saw him . . .”
In this particular case, there is a fan which is mounted in the cover of this pit style furnace. Most pit furnaces are cylindrical in design; however, I have seen them rectangular in design. Some of them have a retort inside them; unlike the picture of the box furnace with the retort, the retort is typically not removable, in this case. Of course, there are exceptions. There are nitriding furnaces that have removable retorts.
I think this is a very distinctive design. If you walked into a heat treat shop, you’d say, “You know, that’s either a box furnace or an oven.” Or, if you looked at this style of furnace, you can clearly see it’s a pit furnace, or what we call a pit furnace.
Two other examples, one of which is just to give you an idea of what we call an “integral quench furnace.” I think this is a good example of one:
"An integral quench furnace, an in-out furnace" Source: Dan Herring
They’re made by a number of manufacturers. The integral quench furnace is probably one of the more common furnaces you’re able to see. It has, in this case, an oil quench tank in front and a heating chamber behind.
This would be an “in-out” furnace; the workload goes in the front door and comes out the front door. But once the workload is loaded into an area over the quench tank (which we call the vestibule), an inner door will open. The load will transfer into the heating chamber in back. That inner door will close, the workload will be heated and either brought up to austenitizing temperature, carburized or carbonitrided, the inner door will then open, the load will be transferred onto an elevator and either lowered down into a quench tank (typically oil) or, if the unit is equipped with a top cool, the load is brought up into the top cool chamber to slowly cool.
These styles of furnaces do processes like hardening, carburizing, carbonitriding, annealing, and normalizing. You typically don’t do stress relief in them, but I’m sure people have. These furnaces have a wide variety of uses and are quite popular. Again, the style is very distinctive.
They typically run a combustible atmosphere, and you can see some of that atmosphere burning out at the front door area.
There are also, what we call, continuous furnaces or continuous atmosphere furnaces. They are furnaces where you have a workload and somehow the workload is moving through the furnace. A good example of that is a mesh belt conveyor furnace.
There are also what we call incline conveyor, or humpback-style furnaces. The mesh belts are sometimes replaced, if the loads are very heavy, with a cast belt: a cast link belt furnace. The furnaces can sometimes look like a donut, or cylindrical, where the hearth rotates around. We put the workload in, it rotates around, and either comes out the same door or comes out a second door.
A lot of times, rotary hearth furnaces have a press quench associated with them. You’re heating a part, or reheating a part in some cases, getting it up to temperature, removing it, and putting it into a press that comes down and tries to quench it by holding it so that you reduce the distortion.
There are other styles of furnaces typical of the “faster” industry which are rotary drums. Those furnaces you would load parts into, and you have an incline drum (typically, they’re inclined) with flights inside it. The parts tumble from flight to flight as they go through the furnace, and then usually dump at the end of the furnace into a quench tank.
For very heavy loads, there are what we call walking beam furnaces where you put a workload into the furnace. A beam lifts it, moves it forward, and drops it back down. Walking beam furnaces can handle tremendous weights; 10,000 to 100,000 lbs in a walking beam is not unusual. Any of the other furnaces we’re looking at wouldn’t have nearly that type of capacity.
There are some other fun furnaces: shaker furnaces. How would you like to work in a plant where the furnace floor is continuously vibrating, usually with a pneumatic cylinder so it makes a tremendous rattle, all 8 or 10 hours of your shift? That and a bottle of Excedrin will help you in the evening.
As a last example, the monorail type furnaces where we saw that you hang parts on hooks. The hooks go through the furnace and heat the parts.
I’ll show you just a couple of examples of those. These are not designed to cover all the styles of furnaces but this one you might find interesting.
"A humpback style furnace" Source: Dan Herring
This is a typical continuous furnace. This would be a humpback style furnace where the parts actually go up an incline to a horizontal chamber and then go down the other side and come out the other end. These furnaces typically use atmospheres like hydrogen, which is lighter than air and takes advantage of the fact that hydrogen will stay up inside the chamber and not migrate (or at least not a lot of it) to floor level.
Atmosphere Furnaces Q&A (47:30)
Evelyn Thompson: Are the inclined sections of the furnace heated? Why do the parts need to go up an incline? Just to get to the heated part of the furnace?
Dan Herring: If you’re using an atmosphere such as hydrogen, it’s much lighter than air. If you had a horizontal furnace just at, let’s say, 42 inches in height running through horizontally, the hydrogen inside the furnace would tend to wind up being at the top of the chamber or the top of the furnace, whereas the parts are running beneath it! So, the benefit of hydrogen is lost because the parts are down here, and the hydrogen tends to be up here.
By using an incline conveyor, once you go up the incline, the hydrogen covers the entire chamber and therefore the parts are exposed to the atmosphere.
I did a study a few years ago: About 5–6% of the types of mesh belt furnaces in industry are actually this incline conveyor type.
Another good example is the fact that people like to run stainless steel cookware. I’ve seen pots, pans, sinks, etc. Sometimes you need a door opening of 20 or 24 inches high to allow a sink body to pass into it. Well, if that were a conventional, horizontal furnace, you’re limited to, perhaps, 9 to maybe, at most, 12 inches of height.
Typically you never want to go that high, if you can help it. 4–6 inches would be typical. So, there would be a tremendous safety hazard, among other things, to try to run a door opening that’s 24 inches high. But in an incline furnace, the height of the door can be 20, 24, 36 inches high. The chamber is at an 11° angle, and you must get up to the heat zone, but they run very safely at that.
Karen Gantzer: Could you explain what a retort is?
Dan Herring: Think of a retort — there are two types — but think of one as a sealed can, a can with a lid you can open, put parts in and then put the lid back on. The retort we saw in that box style furnace is that type. It is a sealed container. We typically call that a retort.
Now, in that pit furnace we saw, there could be a retort inside that one and they could be sealed containers, but typically they’re just open sides, that are made of alloy. Sometimes we call those “retorts” as opposed to “muffles” or “shrouds,” in another case. Muffles don’t have to be a sealed container, but they typically are. That’s the way to think of them.
Karen Gantzer: Thank you, Dan, I appreciate that.
Bethany Leone: Dan, thank you for joining us. It was really a valuable time.
The Metal Treating Institute (MTI), recently held its 2023 Spring Meeting in Naples, FL. The three-day event included a mixture of business and fun with highlights including money raised for the scholarship fund, keynote speaker Joe Theismann, and educational/informative sessions for attendees.
MTI CEO Tom Morrison discussed the diversity of the events encapsulated in the three days of the meeting:
"What is great about MTI’s Spring Meeting is when you have the best minds in heat treating in one room, only great things can happen. Through key experts and round table discussions, MTI members worked through key issues like workforce development, lean manufacturing, predictive maintenance, and managing costs in inflationary times. MTI also raised $35,000 for the MTI Educational Foundation through raffling off a series of NFL jersey’s, footballs and helmets signed by MTI’s featured speaker, Super Bowl winning quarterback, Joe Theismann from the Washington Redskins."
MTI Board of Directors under the leadership of President Jim Orr (center) meets to help guide the organization to greater heights. Source: Heat Treat Today
L-R: Jim Orr, Penna Flame & MTI President; Robert & Judy Rudy, Queen City Steel Treating; Joe Theismann, Featured Speaker; Doug Glenn, Heat Treat Today & MTI Educational Foundation Treasurer Source: Heat Treat Today
L-R: Joe Theismann, Featured Speaker; Lesley Wright, Wirco, Inc. Source: Heat Treat Today
L-R: April Uhlenburg, former MTI First Lady & Tom Morrison, MTI CEO Source: Heat Treat Today
L-R: Doug Glenn, publisher of Heat Treat Today & MTI Educational Foundation Treasure awards a custom Washington Redskins helmet to the highest bidders – Leslie & Chad Wright of Wirco, Inc. Also pictured is DL Wright, Wirco, and George Motes, who custom designed the helmet. Source: Heat Treat Today
L-R: Stacey Liebke, ECM USA & Karen Gantzer, Associate Publisher of Heat Treat Today. Source: Heat Treat Today
Joe Theismann autographs the back of Jim Orr, Penna Flame & current MTI President during an MTI Educational Foundation fundraising event with raised in excess of $35,000. Source: Heat Treat Today
MTI Spring Meeting evening dinner at the Naples Grand Hotel, Naples, FL Source: Heat Treat Today
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Watching the calendar phase from one year to the next has us all thinking about change. Karen Gantzer, senior editor and associate publisher of Heat Treat Today, gives insight to a change happening within the Heat Treat Today team. The team is thankful for the work of both Karen Gantzer and Bethany Leone and look forward to the new year and their new roles!
This article first appeared inHeat Treat Today'sDecember 2022 Medical and Energyprint edition. Feel free to contact Bethany Leone at bethany@heattreattoday.com if you have a question, comment, or any editorial contribution you’d like to submit.
Transitions. How appropriate as we look at 2023 approaching without hesitation. We have no choice but to welcome this new year, preferably with joy and perhaps a child like anticipation of the new adventures to come.
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One of the transitions taking place now, albeit an intentionally slow and steady one, is the move of all the print responsibilities at Heat Treat Today from my plate to Bethany Leone’s as she continues to assume the managing editor role.
I’ve been leading the editorial team for the past several years as we’ve expanded to eight annual print magazines. I have loved helping to produce them each quarter, and honestly, it’s been difficult passing the baton of this responsibility. Not because I don’t think Bethany can do it — I know she will do a phenomenal job in leading the team. I’m seeing it now and am so stoked!
No, it’s because I kind of see the magazine as my “baby.” It’s hard to give it up! Can anyone relate? When you work on a project and see it grow, how exciting and rewarding. To build our team and watch them pivot when necessary and contribute creative and thoughtful ideas to help better serve has truly been energizing and exciting. I think it’s because I love experiencing the process and seeing that magazine in print.
However, the time has come for Bethany to receive the complete baton hand off. (If you ever ran on a relay team and practiced those hand offs, do you remember running with your hand outstretched behind you and adjusting your speed so that you could achieve the perfect transition of the baton from your teammate’s hand to yours without dropping the baton?!) Bethany has her hand in perfect position to receive the baton and I’m looking forward to passing it to her smoothly and completely so that she can run with confidence and vigor.
I’m not leaving Heat Treat Today, just transitioning into new responsibilities — that of associate publisher and senior editor. I’ll still be able to be part of the print publication from 20,000 feet, just not up close and personal (for which Bethany will be incredibly thankful)! I’m looking forward to working on special projects and learning other facets of the publishing world.
So, in February 2023’s Air and AtmosphereHeat Treat magazine, you’ll see Bethany’s picture on this page and enjoy her column in each issue, and you’ll know then that hand off went down without a hitch!
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The 2022 Furnaces North America event in Indianapolis was an unforgettable experience! Karen Gantzer, senior editor and associate publisher of Heat Treat Today, shares about the FNA show with the Heat Treat Today team.
This article first appeared inHeat Treat Today's November 2022 vacuumprint edition. Feel free to contact Karen Gantzer at karen@heattreattoday.com if you have a question, comment, or any editorial contribution you’d like to submit.
Well, the Heat Treat Today team is still riding high from our time at Furnaces North America a few weeks ago in Indianapolis. If you’ve had the opportunity to meet, talk, or work with any of us, you know how passionate we are about the industry, our work in helping you become better informed, and most importantly all of you! We truly love people and building relationships.
Being with many of you and connecting in person is energizing for us! It sure was a full week, but we came home with overflowing emotional tanks because we not only experienced FNA as a team together, but we were also able to have meaningful conversations with you! So, I thought it would be fun for you to hear special FNA highlights from several of the Heat Treat Today team.
Bethany Leone, our managing editor shared: “Breaking bread with 40 Under 40 people in the concessions, sharing chocolate with attendees in the booth, and clinking glasses with the Heat Treat Today family in the evening. It is the joining together and hearing the humanity of so many special people in our lives, whom I only email behind Calibri Light Font Type size 11. “FNA was more. More fun, more lively, more meaningful than I thought. As someone who enjoys anonymity, it was a surprising joy to meet more people face-to-face and strategize ways that the editorial team could help readers and authors. The work to be done beneath my feet was more than I imagined, so much so that I couldn’t leave our booth the first day, save for lunch! Those ‘more’ memories continue to flood my mind, even as I type ‘I’m so sorry I missed you’ to the many people I didn’t get to meet.”
A common theme amongst our team was walking the floor and visiting with you. Lauren Porter, production manager and first-time attendee said: “For me, the highlight of FNA was walking around the exhibit hall on Tuesday morning feeling the room fill with energy! Seeing so many people I had met — but never face to face — was really fun.”
l to r: Ben Bootsma and Wilder Porter
This year we gave away Heat TreatKids shirts. They were a hit with both attendees and staff Alyssa Bootsma, social media editor/copy editor, expressed her favorite memories: “I LOVED handing out the Heat TreatKids T-shirts. It brought so much joy to those parents and relatives. I also loved having lunch with some of the 40 Under 40 honorees. We had fun conversations, and it was great to meet them. Of course, I absolutely loved being with the Heat Treat Today team. You all are such a joy to be around. It was also great to be able to meet people on the show floor or catch up with people we met last year at the Heat Treat Show.”
The first lady of Heat Treat Today, Mary Glenn, said: “I loved having everyone together and hearing how our magazines are helping businesses grow!”
Administrator Ellen Porter shared: “Working with our Team, in person, is such a great feeling of community. That feeling only builds when you get to go to a show and see all the smiling faces of the people we email with regularly, in the greater Heat Treat World. It was great!”
Closing our reflections is our publisher and founder Doug Glenn whose sentiments are shared by us all: “Having (almost) the entire team in one place at one time was really fulfilling and enjoyable. Being a remote company, the opportunities we have for face-to-face interactions are very limited. The time at FNA was especially enjoyable because not only were we together, but we also shared a common mission: get to know our customers and prospects so that we can be better informed about how to help them. The dinner we had together (with a couple of spouses and two honored guests) was also a wonderful time.
“Another major highlight is the satisfaction of seeing the show so successful since this was the first time that Heat Treat Today was the official media sponsor. It seems that our audience showed up and was quite engaged. Getting to meet a handful of our 40 Under 40 honorees was also a super memory for me.”
Until the next time; thanks for the memories!
Main Photo Caption: Heat TreatTodayTeam: (back row): Michelle Ritenour, Ellen Porter, Sarah Maffet, Bethany Leone, Lauren Porter, Alyssa Bootsma; (Front row): Karen Gantzer, Doug Glenn, Mary Glenn
Seeing behind the scenes of everyday processes, seeing the previously unknown "how," can be an "Aha" moment. Karen Gantzer, senior editor and associate publisher of Heat Treat Today, shares about two such "Aha" experiences for the Heat Treat Today team.
This article first appeared inHeat Treat Today'sAugust 2022 Automotiveprint edition. Feel free to contact Karen Gantzer at karen@heattreattoday.com if you have a question, comment, or any editorial contribution you’d like to submit.
It was the summer between my junior and senior year at college. I had secured a sports internship at WLWT, a television station in Cincinnati, Ohio. The opportunity to experience many behind the scene and front of the camera exposures was invaluable and rewarding. One memory that has stuck with me all these years was the first time I saw the meteorologist’s segment from behind the camera while she was on the newscast. She was standing in front of a green screen with a monitor off to the side explaining weather fronts and forecasts. I stood there in wonder. It looked totally different from the station side of things and today, I can’t watch a weather segment without thinking of the blank green screen!
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Have you ever had that experience? Completely blown away by seeing a common or everyday product, process, or presentation whose behind the scenes production was, until the point you saw it, unknown to you. I suppose one could describe it as an “Aha” moment. Well, in early June, the Heat Treat Today team had one of those memory-making trips that we’ll not soon forget.
We had the privilege of visiting the fine folks at ThermTech in Waukesha, Wisconsin. Mary Springer and Chuck Hartwig along with their experienced team shared their expertise and insights as they led us on tours of their facility. How fun it was to see some of the industry vocabulary we put on paper come to life! To actually see everything from the fiery furnaces and the products being heat treated to the pre-furnace parts prep and huge baskets that are used, it was a moment that connected the industry words we work with to the actual processes. We will not forget the sights, smells, temperatures, kindness, and generosity of our time at ThermTech.
Heat TreatToday Team: Doug, Bethany, Lauren, Michelle G-P, Alyssa, Karen, Michelle R., Ellen
The next day, the Heat Treat Today team was graciously hosted by the Quad Graphics folks who print our eight annual magazines. Being divided into a few smaller groups, we each had our own
Quad expert who toured us through the vast and expansive printing facility. To see the incredible precision that it takes to get each magazine from our PDFs to the tangible copies you hold in your hands is truly a sight to behold. From the massive rolls of paper being stored wherever there is available floor space (and, yes, there is a paper shortage) to witnessing the inking, folding, and binding processes gave us all pause to: first recognize the importance for accuracy in our processes, and second to marvel at the many highly skilled individuals it takes to produce each issue. Truly “Aha” moments!
I’m thankful for the opportunity we had to experience these visits as a team and that we can still marvel and appreciate those once unknown processes.
When I view baskets when running errands that remind me of the ones at ThermTech, I’ll remember what and how they do what they do. And, it’s safe to say, when I look at any magazine on the rack, I will see all the machinations it went through from conception to publication. What a grand time to be alive!
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Not every day is a wedding day, so what are the small goals that keep the needle moving forward? Karen Gantzer, associate publisher of Heat Treat Today, leans into this idea in her column about celebrating the "small wins" even as we rejoice in the grand moments of life.
This article first appeared inHeat Treat Today'sMay 2022 Induction Heating print edition. Feel free to contact Karen Gantzer at karen@heattreattoday.com if you have a question, comment, or any editorial contribution you’d like to submit.
Karen Gantzer Associate Publisher Heat TreatToday
Our youngest son will be getting married in two weeks and our third grandson is due to make his entry into the family in mid-May. These are huge celebrations to be sure, and Team Gantzer is excitedly anticipating these life-changing events with great joy.
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I’m sure we can all recall those worthy milestones that we recognized with the appropriate amount of fanfare and recognition. These celebrations are not only fun for the honorees but are also special for those doing the honoring. For the graduate or the one getting promoted, it’s an occasion to highlight the “how” and the “why” of the accolade. For the bride and groom, it’s the collective community sharing in the joy of love and family. The newborn child is representative of life and hope. And the celebration of a life well lived inspires us remaining to cherish each day, pivot if we need to, and look for the opportunities to make a difference in the lives of others.
These remarkable celebrations, though, have been paved with small nondescript victories — victories that may have come at a cost. But do we celebrate those small wins? Or ignore them because they’re not the prominent ones?
We surely don’t want to get into the mentality of the “participation trophy” that diminishes excellence and winners by celebrating every little jot and tittle of a project. But what about those rhythms that help to move the needle forward, whether it be the breakthrough in a particular relationship that was inhibiting growth or fine tuning a habit that needed attention and now will aid, instead of hinder, production? Don’t those deserve a happy dance, too?
"These remarkable celebrations, though, have been paved with small nondescript victories — victories that may have come at a cost. But do we celebrate those small wins?" --Karen Gantzer
Lately, I have been thinking of those small steps needed to make the big goals — earthly and spiritual — a reality and full of impact for not only ourselves, but also for others. It was a tribute, written by a granddaughter to the legacy of her Jesus-loving grandfather who recently passed away that gave me pause to consider how important the small things are in the journey. Here is a brief excerpt by Raechel Myers about Richard Pennington: “The legacy he leaves is the one I hope to someday leave as well: he was a man whose life and rhythms were shaped around his relationship with Christ. Certain things were fixed in his days and weeks and everything else had to earn its way in.”
“[And] everything else had to earn its way in.” I have read and re-read her tribute many times and I keep coming back to this one part. What/who is shaping my life? What things are fixed? And what is already in my life that should have had to earn its way in?
The answers to these questions are important as we set goals and prepare for success. Whether it’s a business or personal goal, remember to assess the small wins along the way and celebrate them as heartily as the major ones, for they bring life and contribute to a rich legacy.
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Heat Treat Radio host, Doug Glenn, and several otherHeat Treat Today team members sit down with long-time industry expert Dan Herring, The Heat Treat Doctor® of the HERRING GROUP, to finish the conversation about mill processes and production. Enjoy this third informative Lunch & Learn with Heat Treat Today.
Below, you can watch the video, listen to the podcast by clicking on the audio play button, or read an edited transcript.
The following transcript has been edited for your reading enjoyment.
Dan Herring (DH): When it comes to heat treating, the mill will do what we typically call ‘basic operations.’ They will anneal the material and, if you’ll recall, annealing is a softening operation (it does other things, but we will consider it, for the purpose of this discussion, a softening operation) so that the steel you order from the mill will be in a form that you can then manufacture a product from. You can machine it, you can drill it, you can bend it and things of this nature.
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There are various forms and various types of steel that can be ordered directly from the mill. So, the mill typically does annealing operations and normalizing operations. The difference between annealing and normalizing is that annealing has a slower cooling rate than normalizing does.
In the aluminum industry, we don’t talk about normalizing but talk about homogenizing. Homogenizing is to aluminum what normalizing is to steel; it’s a crude analogy, but it’s true. The mill can do other processes; they can do other heat treatments, they can do specialized rolling and things of this nature to give you enhanced mechanical properties. In today’s world, there is a lot of what we call “custom” or “specialty mills” that can manufacture very specialized products. There are mills that primarily make pipe and tube, there are mills that make primarily wire, there are mills that make primarily strip. There are some very customer-specialized mills out there. In general, a mill will produce most of the type of products that we see or use in industry (or the steel for those products), and they will make it in a form that is usable for the end user and heat treated to a condition where the end user can make a product with it. Now, obviously, once you make a product, you may then have to further heat treat that product, for example, to harden it or to give it certain characteristics that you need. We’ll talk about those things in later discussions about this.
What I did want to talk about is the types of steel that are produced by the mills. I’ll do this, hopefully, in a very, very broad context, but I think it will make sense to everybody. Again, metallurgists aren’t known too much for their creativity, so we start out with something called carbon steel. Very original. There is low carbon steel, medium carbon steel and high carbon steel. Low carbon steel has low carbon, medium carbon steel has medium carbon, and a high carbon steel has high carbon.
Now, to be more serious, a low carbon steel typically has less than or equal to 0.3% carbon, or less than 0.3% carbon. A medium carbon steel has between .3% carbon and .6% carbon, and a high carbon steel is greater than .6% carbon. An example of a medium carbon steel might be a 1050 or 1055 grade of steel. Those are commonly used for stampings, for example. So, all of your seatbelt, both the tongue and the receptacle are made of a 1050/1055 steel and they’re austempered to give them both strength and toughness so that in an accident, the buckle won’t shatter because it’s hard but brittle and it won’t bend abnormally and therefore release because it has inherent toughness.
So, there are various things you do with these carbon steels in the heat treat mill to enhance their properties. Carbon steels are used because they’re low cost and they’re produced in tremendous quantities. If you went to a hardware store and bought a piece of steel, it is very likely it will be a simple carbon steel.
On the other hand, we also make alloy steels and, interestingly enough, there are low alloy steels, medium alloy steels, and guess what, high alloy steels. Again, metallurgists are very creative with their names. But idea here is you get higher strength than a carbon steel, a little better wear resistance and toughness, you get a little better corrosion resistance, for example, you might even get some specialized electrical properties and things like this.
But low carbon steel, just to go back to that for a minute, as I said, is produced in huge quantities. Examples are steel for buildings, steel for bridges, steel for ships. We learned our lesson, by the way, with the Titanic; we got the steel right this time. The problem with that steel, by the way, was high in sulfur which embrittled it, interestingly enough, in cold water. So, when it hit the iceberg, the steel shattered because it was brittle because it had too much sulfur. But we learned our lesson.
Titanic, 1912 Source: Wikipedia
There are also various construction materials; anything from a wire that’s used in fencing to automotive bodies to storage tanks to different devices.
When you get into medium carbon steels, because they have a little better strength and a little better wear resistance, you can use them for forgings, you can use them for high strength castings. So, in other words, if you’re producing gears or axles or crank shafts, you might want to consider a medium carbon steel, or seatbelt components as we talked about.
Then there is the family of high carbon steels. Again, they can be heat treated to give you extremely high hardness and strength. Now, they’re obviously more expensive than medium carbon or low carbon steels, but when you’re making knives and cutlery components, (knives and scissors, for example), when you’re making springs, when you’re making tools and dyes. Railroad wheels are another example of something that might be made out of a high carbon steel. As a result of this, the type of product that your company is producing, means that you’re going to order a certain type of steel that you can use to make your product and give it the longevity or the life that your customers are expecting.
One of the things about steel that differentiates it from aluminum: Aluminum has a very good strength to weight ratio. But so again does steel, but obviously the strength to weight ratio, the weight is specifically much more, from that standpoint. But we can take steels that we produce from the mill, and we can do processes like quench and temper them. If we do that, we can make things like pressure vessels, we can make the bodies of submarines, for example, we can make various pressurized containers and things.
Stainless steel pots Source-Justus Menke at Unsplash.com
There are a lot of different things we can do with steels to enhance the products that we’re producing. Besides just low carbon steel or carbon steels and alloy steels, we then can go into the family of stainless steels, for example. Most people think of stainless steels as being corrosion resistant. I’ll warn you that not all stainless steels, however, are corrosion resistant; some of them can corrode in certain medias or chemicals, if you will. But with stainless steels, a good example of that is food processing containers or piping or things that will hold food or food products, and again, we can make with stainless steels a variety of different products. We can make different components for buildings, for example, or for trim components and things.
Besides stainless steels, of course, we can make tool steels. Now, tool steels represents a very, very high alloy steel. The alloying content of tool steels is typically 30 to maybe 50% alloying elements: molybdenum and vanadium and chromium and these types of materials. As a result, we can make a lot of dyes and we can make a lot of cutting tools, we can make taps and other devices that are used to machine other metals, if you will. So, tool steels have a lot of application.
But there are a lot of specialty steels that are made by the mills, as well. One example of that, that I like to talk about or think about, is spring steels because you can make various things like knives and scraper blades, putty knives, for example, besides cutlery knives. You can make reeds for musical instruments, the vibrating instruments in the orchestra, if you will. You can make springs and you can make tape measures, tapes and rules and things of this nature out of these various spring steels, if you will.
Depending on what your end-use application is, the bottom line here is that whatever your end-use application is, there is a particular type of steel that you should be using and there is a form of that steel that you can use. Again, those steels can be produced by a variety of different processes; they can be forged, they can be rolled, hot and cold rolled, again. And when I’m talking about hot rolling, I’m talking about temperatures in typically the 1800-degree Fahrenheit to 2200/2300-degree Fahrenheit range. When I talk about hot rolling, the metal is, indeed, hot, if you will.
By the way, roughly, iron will melt at around 2800 degrees Fahrenheit, just to give you a perspective on that, if you will.
The key to all this is that the form that is produced by the mill meets the needs of their customers and their customers’ applications. If you need a plate, for example, they will produce plate in various sizes and thicknesses.
Rolling direction Source: Barnshaws Group
By the way, just a quick note, and this is for all the heat treaters out there: Be careful of the rolling direction in which the plate was produced. We have found that if you stamp or cut component parts out of a plate with the rolling direction, or transverse or across the rolling direction, you can get vastly different properties out of the products. It’s amazing that you can get tremendous distortion differences from heat treated products depending on the rolling direction. If you’re stamping or forming out of a plate, you’re transverse or in line with the rolling direction. Most people don’t even think of that. They take the plate, they move it into the stamping machine, and they could care less about the rolling direction. Then, when the poor heat treater does his heat treating and distorts all the parts, the man comes back and says, “What’s wrong?”
By the way, that little example took only nine years of my life to solve. We had some, what are called, "springs" that are the backing on a knife. When you open a knife blade, there is a member that it’s attached to called a spring. Those springs were distorting horribly after being oil-quenched in an interval quench furnace. It happened to be a conversation around the coffee machine where one of the guys made the comment that, “You know, it’s really funny, we never had problems with distortion until we got that new stamping machine in.” Low and behold, in investigating it, the old machine took the plate in one direction, the new machine had to take the plate in a different direction and it rotated. . . . End result.
So, I guess for everybody listening, the key to this is that no matter what the material is that’s being produced, we need to use it sometimes in its cast form, we need to use it sometimes in its finished forms, which again can be bar and sheet and plate and wire and tube and things of this nature. And to get those shapes, we need to do things like hot and cold rolling, we need to do forging, we need to do operations like piercing to actually produce rings and things of this nature. So, although I didn’t go all the details about that, there is a lot of information out there about it. I wanted to set the stage for it to say that it’s the end-use application by the customer that fuels the type of steel being produced and fuels the form in which the steel is produced.
Perhaps as a last comment, on my end anyway, at this point, is the fact that a mill is a business just like anyone else’s business. We’re always looking for ways to cut costs, (not cut corners, but reduce cost), and mills have found that in the old days — and the old days weren’t necessarily the “good old days” — a mill made everything; they made all types of steel, they made all types of shapes and forms. But today, a lot of mills are saying it’s not economical to produce that particular type of steel or that particular form of steel, so we’ll leave that steel production to someone else, and we’ll only concentrate on high volume production.
You know, it’s very producing steel, a typical heated steel (and people will probably correct me on this), is somewhere in the order to 330,000 pounds of steel. So, if you’re a small manufacturer and don’t happen to need 330,000 pounds of steel, you have to go to a distributor and, more or less, maybe compromise a little bit to get the steel that you need. But the mills are producing large quantities of steel and very specialty steel grades, in general, today.
Doug Glenn (DG): It’s essentially specialization of labor so it helps keep each individual mill’s cost down, but it doesn’t have the variety it used to.
Let’s open up for questions, really quick. I’ve got one if nobody has one, but I hope somebody else has one. So, fire away if you’ve got one.
Carbon steel gate valve Source: Matmatch
Bethany Leone (BL): When you said that, Doug, my question jumped out of my head. I had 3 questions though but the ones I remember aren’t that important. One is — I recently visited an old blast furnace in Pittsburgh, Carrie Blast Furnaces; everybody should go, if you’re in the Pittsburgh area), so some of this sounds familiar. The second thing I was wondering is just how high can the carbon percentages go in carbon steels, .6%+, right?
DH: Yes, greater than .6%, and it’s not uncommon for carbon in various types of steels to go over 1%. It typically can go in certain tool steels and things higher than that. But one of the things that differentiates a steel from a cast iron is the percentage of carbon in the material. And carbon over 2% is considered a cast iron as opposed to a steel. Steel has a carbon percentage from .008 all the way up to 2%. That’s a great question and something to be aware of. When you buy a cast iron skillet, for example, you’re getting a material that has greater than 2% carbon in it.
BL: The other question I had is sort of more on the business end, if you know any of this, is- with the high energy that it takes to process iron, I imagine there have been efforts to try to reduce costs to produce energy that’s used to be a technology and innovation and especially right now with many people concerned with sustainability in those practices, are there ways that maybe even clients have influenced how businesses iron manufacturers in the iron manufacturing world have been trying to keep those environmental loads down, do you know?
DH: That’s a very intriguing question. I don’t have all the facts and information on it, but I’ll share a few things. As opposed to the production of aluminum, which is primarily using electricity, steel production uses typically natural gas. There were, in the old days, oil-fired equipment and things of this nature but today it’s typically gas-fired furnaces and things of this nature. Now, I have to be careful when I say that because some of the steel refining methods, (for example, the vacuum arc remelting furnaces and things of this nature), again, use carbon electrodes and use electricity, if you will, in the process. But essentially, what they’re trying to do is they’re trying to, for example, capture waste heat and reuse it to preheat different materials and processes and things of this nature, and they’re using methods that are trying to make the overall equipment more energy-friendly; if you will, better insulations, better fit of components than the old days when they didn’t care too much about if we got heat pouring out into the shop, we don’t care. Today, we really care about those things.
But steelmaking, again — for a different reason than aluminum — is a very energy intensive process; it uses a lot of energy to produce steel.
I’ll make a quick comment also, and I’m not saying this especially from anyone internationally who happens to be listening in to this: I’m not saying this is an “America only” comment, if you will, but in 1900, the largest industry, the largest company in the U.S. was U.S. Steel. United States Steel was the number one most profitable company in the country. If you think about it, throughout what would be the 20th century, steel and steel production has fueled, if you will, the American economy. We’ve since transitioned to other more angelic materials, if I can use that phrase; I won’t define it. However, who do you think produces over 50% of the world’s steel today? Anyone want to guess?
DG: The U.S.?
DH: No! China. And where is the manufacturing growth taking place? So, the production of aluminum, the production of steel, fuels manufacturing is my message here.
Yes, there are environmental consequences, but I often use the phrase and, again, this is not intended to be insultive to any one country, but for all the recycling, for all the energy saving, for all the environmental progress we can make in the United States, if we could reduce coal consumption in China (and India, of course), it would have major, major impact on the environment. And that’s not having 100-year-old steel mills, like we have here in the U.S., will go a long way, if you will.
DG: I’m going to give you 30 seconds, Dan, to answer one more question, okay? Here’s the question: Aluminum doesn’t rust, most steels do. Why is that?
DH: In simple terms, because aluminum reforms an aluminum oxide on the surface and that oxide is impenetrable, virtually, to further oxidation, whereas iron produces an iron oxide on the surface in the form of rust, it flakes off and you can reoxidize the surface. Now, there are steels — core10 is an example — self-rusting steels, that once they rust, they don’t reoxidize, but that’s the basic difference, Doug, between them.
DG: Perfect, perfect.
Alright guys. Thank you very much, Dan. I appreciate it. We’re going to get you on deck for another one here pretty soon on another topic, but we appreciate your expertise.
DH: Always a pleasure and, as I’ve said, I’ve reduced 3,000 pages into 30 minutes so hopefully people that are interested will read up more on these processes.
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