A Pennsylvania heat treat supplier recently shipped and commissioned two power supplies used in a continuous brazing furnace for a tool manufacturing company. The new power supplies, rated 125 kW supply and 100 kW, were designed as direct replacements for a pair of existing, obsolete power supplies that continuously failed.
Magnetic Specialties, Inc's power supplies reduce furnace downtime and provide tighter regulation of the furnace temperature which delivers more consistent quality of the braze parts. The brazing furnace has silicon carbide heating elements, which increase in resistance as they age. To compensate for this, the output transformers feature a tapped secondary winding. As the elements age, the client can select a higher output voltage range via the tap switch. The client will use the metering feedback to know when the tap needs to be changed.
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Each Nadcap audit is different, but each accreditation involves key elements that help heat treaters maintain quality and safety standards. Finding instances of nonconformance and implementing corrective actions are two main ways the Nadcap process helps heat treaters keep a high standard. What are the steps needed to complete the Nadcap process?
In this best of the web article, read a break down of the entire Nadcap process. From practical tips like performing a few internal audits before submitting one for review to understanding the difference between minor and major nonconformances, this article will be your go-to on all things Nadcap.
An excerpt:
[blockquote author="" style="1"]Focusing on maintaining global quality standards not only helps ensure the safety of all who use these products, but also helps you continually improve and refine your heat-treatment processes to provide your customers with the best product quality possible.[/blockquote]
At Heat TreatToday, we want to make sure everyone in the North American heat treat industry is well informed so they can be happier and make better decisions. With that in mind, we have been growing our library of Spanish heat treating content.
Below, click the blue headings to learn from Víctor Zacarías about pyrometry standards in the aerospace and automotive industries, from Carlos Carrasco about selecting heat treating equipment, from Bill Munn about leadership and motivation, and from Erika Zarazúa about CQI-9's probe method A. If you'd like to view this content in English, click the America flag icon.
Víctor Zacarías General Director Global Thermal Solutions Mexico
"Las operaciones de tratamiento térmico son percibidas generalmente como cajas negras cuyos resultados son poco predecibles. Si bien, entendemos los mecanismos físicos involucrados para modificar las propiedades de un material, los hornos de tratamiento térmico son sistemas termodinámicamente imperfectos, y por ende los resultados finales en ocasiones también lo son."
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"Heat treatment operations are generally perceived as black boxes whose results are not very predictable. Although we understand the physical mechanisms involved in modifying the properties of a certain material, heat treatment furnaces are thermodynamically imperfect, and sometimes the final results are too."
This article first appeared Heat Treat Today's March 2022 Vacuum Furnace print edition.
Carlos Carrasco Founder Carrasco Hornos Industriales
"Este artículo ayuda a los ingenieros a comprar equipos de tratamiento térmico. Hay muchas razones para seleccionar cuidadosamente los hornos industriales. Uno, es el costo del horno en sí y otro, es que el producto que se está tratando térmicamente afectará los resultados de su empresa."
"There are many reasons to select industrial furnaces carefully. One is the cost of the furnace. Another is realizing heat treating will affect the product and the bottom line. There is more specialized engineering in heat treating equipment than is apparent from the outside."
This article first appeared in Heat Treat Today's November 2021 Vacuum Furnaceprint edition.
Bill Munn Leadership Coach Bill Munn Source: Bill Munn Coaching
Por definición, de aquí se desprende que no se desempeña solo; es más, está posicionado no solo para trabajar en conjunto con otros seres humanos sino también para liderarlos; si su potencial se ha de realizar, puede que ya haya entendido bien que en esas personas reposa la verdadera clave del éxito que a futuro pudiera conseguir ¿Cómo, pues, lograr su compromiso?
By definition, this means that you are not functioning alone. Moreover, you are positioned not only to work with fellow human beings, but to lead them. And if your potential is to be realized, you may already know well that those people are the true key to your future success. So how will you engage them?
This article first appeared in Heat Treat Today's September 2022print edition.
Erika Zarazúa Regional Purchasing Manager Global Thermal Solutions México Source: Global Thermal Solutions México
"Las pruebas SAT deben realizarse a todos los sistemas de control, monitoreo y registro de los equipos de procesamiento térmico. Esto no aplica para los sistemas de ‘alto-límite” cuya única función es la de proteger al horno de un sobre calentamiento."
"System Accuracy Tests (SATs) must be performed on all control, monitoring, and recording systems of thermal processing equipment. This does not apply to “high limit” systems, whose sole function is to protect the furnace from overheating."
This article first appeared in Heat Treat Today's August 2022 Automotive print edition.
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Today’s episode revolves around gun parts: How are they heat treated? How many gun component manufacturers are there in the U.S.? Doug Glenn, publisher ofHeat Treat Today and host of this podcast, and Steve Kowalski, president at Kowalski Heat Treating, dive into this topic and what it takes to heat treat gun parts.
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.
Doug Glenn (DG): Well, welcome to another episode of Heat Treat Radio. I have the immense pleasure of being able to sit down today with Steve Kowalski of Kowalski Heat Treating. Steve, you know, it’s nice to finally sit down with you. We’ve been talking for quite some time about doing this, so first off, welcome to Heat Treat Radio.
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Steve Kowalski (SK): Well, good morning, Glenn. Thank you very much for having me today.
DG: You are very, very welcome. Now, we have to start, as I told you before hit the record button, over your left shoulder there is an interesting ball. You need to tell us about that real quick.
SK: Can you see it?
DG: Yes, yes, we can see it.
SK: For you and folks at home, this is a rubber band ball. For perspective, how’s that? It’s twenty-two plus years in the making.
"For you and folks at home, this is a rubber band ball. For perspective, how’s that? It’s twenty-two plus years in the making." -Steve Kowalski
DG: For those of you who are on the audio only version, it’s about the size of a basketball. Steve was telling us that you guys [Kowalski Heat Treating] have been using only the stuff that comes in the U.S. mail. It’s very impressive. It has nothing, absolutely nothing, to do with heat treating, but I did want to say that it’s pretty interesting.
Anyhow, Steve, we’re going to talk a little bit today about the heat treatment of guns, ammo, and that type of stuff. That’s just to whet the appetite of those who are listening and watching; that’s what we’re going to be talking about a bit, your organization does it.
But I’d like to have you take a minute just to talk about your background, very briefly. I know that it’s a long, long background . . . . ~chuckle~
SK: Careful, careful!
DG: Yes, I know! Trust me, you and I graduated from college the same year, so I know. So, it has been a long background. But briefly, tell the listeners/viewers about you, about the company, and then we’ll jump in with some questions about firearms.
SK: Wonderful. I’m second generation. My dad started the business back in 1975, so I was underage working, yes. Those of us in the commercial heat treat, a lot of us have grown up in businesses where we were the underaged employees. The transition took place about 15 years ago. We started off with one building, roughly 3,000 square feet, to process tools and dyes. Back in the day, Cleveland was one of the tool and dye capitals of the world- we had tons of tool and dye makers. Well, that business has evolved away.
Since 1975, we’ve grown the business to now having nine facilities on our campus, roughly 80,000 square feet, and those of you who know Kowalski Heat Treat, we specialize in those PIA jobs — it’s what we do. If it’s a problem, it’s pretty sure that it’s going to be coming to our facility.
We started in salt bath. Over the years we added high pressure quench vacuum processing, plasma nitriding, plasma nitrocarburizing, heat pyrogenics. One of our divisions specializes in nothing but keeping parts flat- round and flat. You can go to our website at KHTE.com and check out the various divisions and what we do. Basically, in our world today, we rack or assemble 95-97% of everything that comes through this door — it’s specially handled.
DG: The PIA, the “pain in the ass” ones is what you’re talking about. Do you guys have, therefore metallurgists and things of that sort on staff, as well, I assume?
SK: We have 48 people, we have 8 engineers on staff — anything from chemical to mechanical to electrical. We do not have any metallurgists on staff. We have access to great metallurgists in the area.
DG: Cleveland has them.
SK: Oh, my gosh, we actually are blessed here in Cleveland. If you need something — one phone call and we can find it.
You’re from Pittsburgh, aren’t you?
DG: Yes, just north of Pittsburgh. Don’t hold that against me.
SK: No, no, it’s okay — you’ve done remarkably well. ~chuckle~
DG: All things considered, there you go. I appreciate that. How very gracious of you, Steve!
SK: Oh, my pleasure.
Kowalski Heat Treating is a family company. Source: Kowalski Heat Treating
DG: You’re right, though. Cleveland, I think, especially. Ohio, in general, but Cleveland, in general, are kind of like the forging center of the world. There’s just a lot that goes on there. But heat treat, in between Detroit and Cleveland, it’s kind of “heat treat central.”
Well, listen, that’s great. You’ve obviously been very successful. You’re good at what you do. I know it’s still a family business --- you’ve got you and your sister, at least, involved, right?
SK: Sisters, yes, correct. Two sisters are involved: one in the back office and Peggy Andrews is inside sales customer service. You’ve met Peggy.
DG: We’ve met Peggy; we know Peggy. Peggy is wonderful.
SK: And for all of you listening — I’m the quiet one in comparison.
DG: I believe that, now. I’ve met Peggy and she’s great.
Also, you’ve been a little bit humble because you were the president of the Heat Treat Society not too long ago, were you not?
SK: Yes.
DG: Which is quite an honor.
SK: Before me was Roger Jones and after me was Jim Oakes.
DG: Let’s talk firearms for a second. You know, it’s kind of interesting, because when you talk firearms, it’s always a little bit controversial. Obviously, there’s a political side to this conversation. We don’t really want to go down that road too much because we’re just going to talk about heat treatment. But I do want to ask you, which could be slightly bumping up against the political side: Have you seen, recently or in the recent past, any increase in that business that Kowalski is doing as far as firearms go?
"Well, in our firearms business (and I know we’ll be talking about the who, what, where, when, why of firearms and how processing is incredibly important), we work with the DOD (Department of Defense) and very unique programs, we work across the spectrum in the firearms from long guns to handguns and there seems to be a huge misconception in the world on firearms. ATF controls that world from the registration standpoint."
SK: Well, in our firearms business (and I know we’ll be talking about the who, what, where, when, why of firearms and how processing is incredibly important), we work with the DOD (Department of Defense) and very unique programs, we work across the spectrum in the firearms from long guns to handguns and there seems to be a huge misconception in the world on firearms. ATF controls that world from the registration standpoint. Every firearm has a serial number (certain components of it) so it is tracked. Our systems have evolved over the years — we’ve developed specific systems that are very sophisticated to be able to track the product that we process. The key components that require serialization or a serial number — we track them. We do hundreds of thousands of units a year, and they’re all tracked so that you and I can go across the political side. We’re really very, very proud of the fine work that my team does in the firearms industry. Most of our first responders, law enforcement, defense — they require and depend on what we do. I can make it very dramatic, but in reality, if we don’t do our jobs correctly, they can’t do their jobs correctly.
DG: Yes. And it’s somewhat of a life and death thing, too. I mean, if you’ve got malfunction because of a defective heat treat, or for any reason, it can be an issue.
SK: Our business has definitely grown in the last seven years. We’ve built a very good reputation in this industry. If you have a problem, chances are we’re going to be working with you to help you solve your problem. Firearms are extremely highly engineered with very tight tolerances.
DG: It’s kind of interesting, here, because you’re talking about serialization of parts and things of that sort that come in; you’re not getting fully assembled guns — you’re getting parts and pieces. So, you’re able to track— I’m curious, is that tracking a barcode, is it optical — how do you do it?
SK: The answer is “yes” to all of the above. It depends on the customer. If you have a sales agent, you have a serial number or you have a code and, in some cases, some of our customers are moving toward QR codes. So, if you receive in 10,000 units, whatever they may be, well that’s 0 to 10,000 and you need to ship 0 to 10,000 back. If you do not, ATF is notified.
DG: That’s interesting. Types of furnaces: Are you guys running batch furnaces or are you running continuous furnaces?
SK: We do batch. The majority of what we process for the gun world, for the firearms world, would be either salt to salt rack austempering or marquenching, vacuum and actually plasma processing, whether it’s FNC or nitriding. Those three areas, we’re involved with the gun world.
DG: Yes, I was curious, because you hear a lot about, especially. It’s a different market, but in the faster world, you hear fallout. If you’re going through a mesh belt furnace, you know, “Oh well, you lost a few fasteners down on the bottom of the furnace.” That would not work in your . . . .
SK: I can make light and we joke a little bit about it, but you do not want folks with three letters on the back of their coat coming in.
DG: Exactly. If that happened, probably the next interview we’d do with you, you’d be wearing an orange suit and maybe you’d have a roommate.
SK: And I just don’t look good in orange.
DG: So, now, as far as the firearms industry, there are a lot of different metals and materials of that sort, but there are two basic things — I mean, I always talk about it and we talked about this a little bit before we hit the record button: There is ammunition and then there are gun components. You guys do not do ammo, correct?
SK: Correct. That is not a world we’re in. We are in the gun side — all of the components for guns. On any given firearm, you may have, in our particular case, we may be processing 12–15 different components for a handgun — anything from a barrel to a slide to a receiver to a firing pin, ejectors, extractors, triggers, trigger guard — the list goes on. It tends to be a different material; there are different properties that they develop that they need a firing pin versus a trigger guard versus a slot.
DG: Just a quick example if you don’t mind. It’s important for the heat treater to know what they’re doing, obviously, right? Why is that? Can you give us an example of why it is?
On any given firearm, you may have, in our particular case, we may be processing 12–15 different components for a handgun — anything from a barrel to a slide to a receiver to a firing pin, ejectors, extractors, triggers, trigger guard — the list goes on. It tends to be a different material; there are different properties that they develop that they need a firing pin versus a trigger guard versus a slot.
SK: Well, when you say “a barrel” is true. If a barrel is not “true,” straight, no distortion. We’ve all seen various TV shows where the person swings the gun around and the bullet shoots around the corner. No. Doesn’t happen. So, if the barrel isn’t true and hasn’t been processed appropriately and correctly, it’s not going to function the way it was designed.
A firing pin, which is a very distortion-sensitive component- if it’s bent, it doesn’t work. The gun will not fire. We could go on: slides and receivers. If they’re distorted, they’re not going to work. It’s not going to function. So, each component must be processed to achieve dimensional tolerance control. And then metallurgically, the structure: A gun has a very aggressive action.
DG: Mini explosions, basically.
SK: Literally. And so, it’s been designed to support all of that.
DG: The different components that I think about are the firing pin you were mentioning, right? It’s going to have a lot of impact on the shell casing on the firing pin.
SK: In that particular case (and we’re not giving any IP away), but those are austempered for structure. Doug, are you a metallurgist?
DG: No, I am not, actually.
SK: Nor am I. I’m a marketing guy, folks, with experience.
DG: Same here, same here.
SK: The design — if that pin chips, cracks, breaks, it doesn’t fire.
DG: Exactly. So, you’ve got the high impact parts like the firing pin, you’ve got barrels where you want good wear resistance and things of that sort and, obviously, they need to be true and straight. You’ve got springs in a lot of guns, especially your Ruger style where the receiver’s back — those things have to be heat treated appropriately.
Steve, what type of alloys typically are we talking about in some of these different parts?
SK: They range from high carbon materials (1050, 1060, 1070) up to high temp stainlesses, whether it’s 400 series, whether it’s a precipitation hardened series, mid to high alloy materials (4340, 4150) and then, as we get into the specials, the engineering world is continually trying to make a better product- a longer acting product, a more robust product- so we’re starting to see materials that, historically, weren’t used in this area. Plus, things that we don’t deal with, there are many components that are carburized using 8620, 9310, carburized and hardened, for the same purpose: wear and performance.
DG: Being in the Cleveland area, you are kind of in another hub and that’s where a lot of this 3D printing, additive manufacturing; I mean, there’s a lot that goes on there. I think there’s an organization in Youngstown, or in that area, that’s kind of a central hub there. Are you guys seeing any of that, whether it be in firearms or not? Have you had any experience with any of the AM?
SK: The answer is yes. AM is absolutely taking place; it’s incredible. The technology — what you can do today that you couldn’t do two or three years ago and then you have to effectively engineer backward forward, make it, and then make it right, then produce it, thermally process it (maybe); so, it’s one of those.
DG: It’s an interesting and evolving technology.
As a heat treater of gun components, not that you want to help any competitors or anything of that sort….
SK: Heck no, we love all of our competitors who are not working against us, how’s that?
DG: That’s fair enough, that’s fair enough.
As a heat treater, what are the things that jump into your mind that you have to be careful about when heat treating gun components? And if it helps, pick a specific component, whether it be a pin, a barrel or whatever. What do we need to be careful of?
SK: I’m looking up over your head (which is beautiful, by the way) at the sky here in Cleveland, Ohio. The way I’m going to answer this is this: You are dealing with a component that, if we take guns out of it and, say, use medical devices. We’ll use medical devices in lieu of saying guns so people can appreciate where I’m going with this. You have bad players out there — people who are trying to circumvent the system. With medical devices, you need to have approvals — you need to have FDA. It’s very similar in the gun world- you need approvals, you need make sure that they’re making components that comply with, whether it’s the OEMs’ specification or ATF specification being sterilization (making sure things are marked appropriately). Internally, here, we have secure quarantined areas where we do all of this work. Your personnel — I have to be approved to be able to process these parts. My background has to be checked.
This company, my company, approves those people who can touch these components. Internally, we have secure, bonded areas. Parts are bonded in and they are bonded out. Use the terminology you like, but basically, you’re securing from our floor to an area because it is that important. If we’re dealing with the aerospace world or nuclear world, you are going to make sure your systems and processes and procedures are all locked down.
DG: So that’s a procedural, operational uniqueness, let’s say, to handing guns. How about technically? Like in the aerospace industry, you’ve got NADCAP, in automotive you’ve got, you know, in aerospace still you’ve got AMS for pyrometry, CQI-9 and things of that sort. The medical industry, which you mentioned, Steve, has MedAccred and things of that sort. Any such beast in the firearms? I haven’t heard that there is.
SK: Basically, we have overlapped between our guns and gun industry as a whole with the DOD work that we do, so we go back and forth. What you mentioned here, most of those requirements and procedures are already in place. It makes it easier if you’re doing CQI-9 relevant work, you’re not going to start and stop. So, the equipment is already covered in those areas. The procedures — you build them so that you’re not building fourteen different procedural systems. It’s difficult to control.
DG: You’ve already kind of answered this but let me just ask it straightforward just in case there’s something else, and if there’s nothing else, that’s fine. For the people in your company and for you guys, generally speaking, is there any specific training or knowledge or experience that you have to have to be heat treating gun components?
SK: Yes. And those are: one, experience is an incredible teacher and often times. For Kowalski Heat Treat (I can’t speak for competitors, I’ll speak for us), normally, if a product hits our floor, hits our dock, hits my inbox, historically, somebody has had a problem with processing that component — whether it’s distortion, whether it’s metallurgically the properties they’re achieving, whether it’s actually out in the field — you’re my favorite, you’re my test. You’re going to call and say, “Hey, Steve, I got this thing and I’m not happy with its performance and I need to improve its performance. What can we do?” Then you start the entire investigatory process of what have you done, what have you achieved, did you actually test or are you just feeling that what you’re telling me is you’d like to have something better but you don’t know what? So, we have a design team here that will work very closely with your folks to help design a better process, a more robust process. If we’re talking to the general industry, as we are right now, I think we can all agree that the quality and consistency of the materials that we are receiving in today are dramatically different than they were five years ago, eight years ago, ten years ago.
SK: Worse. Worse being not as consistent as they were. Yes, we all have that grade A and four of us will process grade A today and we will get result B. Next week you’re going to get B-, B+, possibly an A, maybe a C.
We’re joking internally, but the first thing most heat treaters do — because, quite frankly, we’re paranoid; the entire world is out to get us and it’s always the heat treaters fault. . . . It’s always our fault. So, the first thing we do when enter into a relationship is we say, “Doug, hi, I’m Steve. I’m sorry.”
DG: Get that out of the way, start out that way.
SK: Then we move forward from there. But that has been a serious challenge on the consistency of the materials coming to us.
DG: So, you guys test all incoming material?
SK: Yes. And don’t use the word “all.” But yes, we have an inspection and we work closely with customers. As you get your material in, send it to us. Before you start making a product, send us something that we will process and validate for you so that you know that what you’ve got will respond the way you thought it’s supposed to respond. Then, we can move forward being more efficient with that.
DG: You’ve hit on this before, too, but I just wanted to see if there are any other comments that you want to make on this and that is the type of equipment that is necessary for doing the heat treating of these gun components. I know you mentioned salt, so you’re in a salt bath, right?
SK: Salt neutral hardening, salt hardening, and then marquenching or austempering, depending on the component. It’s critical. There are a significant number of parts that respond extremely well to rack austemper, rack marquenching. Extremely well. And we’d probably say that our team here, they’re spectacular. I get to talk about it which is really pretty cool. Hey, I’ve got these great people with me that do this great work, and they do! Their job is to make me look good. As you know, your support staff, yes, don’t even say it, I know it’s a fulltime job, it’s never done . . . . ~chuckle~
DG: You took the words out of my mouth! ~chuckle~
SK: So, salt is critical in this industry. Vacuum processing.
DG: Why did you go vacuum, by the way?
SK: With stainlesses and the various materials that we’re currently using, having high pressure quench vacuums/high pressure quench, it allows for a significant amount of flexibility. We can finetune a recipe, or cycle, to achieve properties that the customer needs where it makes it repeatable.
DG: And you’ve got, what, how high pressure? What bar are we? Ten bar quench?
SK: Yes.
DG: So, you’ve got salt to salt, you’ve got high pressure gas quenching coming off of a vacuum heat treat. Anything else?
SK: And then we do plasma nitriding. I will say that we have the technology we have utilized to optimize processing. Is ours the best for everything? Absolutely not. No question about it. And when it’s not, we’re going to say, “Hey, Billy, I need you to call Doug and I need you to tell Doug that Steve said to call him and ask the following three questions. Doug’s got the answer for you.” And your equipment for his application is better than mine; it works best. So, I think anyone in the heat treat world can recall the scars on our backs from the days that we thought we could give you exactly what you need [indiscernable]. It’s not the best answer.
DG: Do you do much heat treating of gun components in straight atmosphere or air furnaces?
SK: We don’t have them.
DG: You don’t have them at all. And do you do induction?
SK: No, not yet. No oil quenching here whatsoever. We’re here in Cleveland in a residential area and we are zero quantity generator of hazardous waste.
DG: Nice. I’m sure your neighbors appreciate that.
SK: Oh, they absolutely do.
DG: If they know.
SK: Oh, they do.
We know what we’re really good at and that’s our work.
DG: A couple more questions on this. We talked about the uniqueness of heat treating gun components because of the traceability and the serialization and all that stuff. Is there anything else technically unique about the heat treatment of any of these gun parts that kind of make them interesting or more of a challenge?
SK: Yes. Have you met my wife?
DG: I don’t believe that I have.
SK: There is a comment that she tells me all the time: Everything that goes through my mind doesn’t have to come out my mouth. She’s incredibly wise and way smarter than I am!
In the heat treating world of gun components, one of the areas that would be critical is it is not a bulk processing world. It’s not about running more and more and more parts at one time. You will not get optimum results. It’s a sensitive process. We’re heat treaters and we’re very sensitive with what we do.
But distortion is critical. The way the parts have been designed, you cannot effectively, in my humble opinion, put them into a 2436 or 3648 basket and max load it — you will not get optimal results. It’s not going to happen. So, there is a tremendous amount of racking.
"In the heat treating world of gun components, one of the areas that would be critical is it is not a bulk processing world. It’s not about running more and more and more parts at one time. You will not get optimum results. It’s a sensitive process. We’re heat treaters and we’re very sensitive with what we do." - Steve Kowalski, Kowalski Heat Treating
DG: That, actually, was my question: Not that you would know this number right off the top of your head or anything, but the percentage of time spend racking, I assume, is higher.
SK: It’s 2:1, 3:1, 4:1, 5:1.
And, for those of your listeners who understand salt processing, we can rack for two days and process for an hour/two hours.
DG: Let’s say it’s just manually intensive, then.
SK: We have an incredible team of individuals here who do things that, if you watch, you’re just like…. In some cases, it’s truly awe-inspiring because they create for us success. They help us learn new ways of processing. It’s not, hey, you’re going to do it the way Steve says. Critical process control, but they provide us the answers on making things better.
DG: I’ve got two other quickie questions for you. We may have already covered them. One was just if there is any common mistakes? I know you guys don’t make mistakes, but . . . .
SK: Heat treaters do not make mistakes!
Source: Kowalski Heat Treating
DG: That’s correct. But is there any common mistakes with the heat treatment of gun components? Because, if you guys really are, as you say, the people that are taking care of the PIA jobs, it’s usually coming from people who have made a mistake.
SK: Yes. It’s when to say no. You and I have talked and we’ve talked to our peers — they’re brilliant people. We tend to all lament, usually, the same thing. Something comes in and it’s not quite right or correct and we don’t say, “Stop. Doug, you did not make this correctly. We can’t do what you want us to do because of you’ve provided to us.” Or the next step would be folks who assume.
But the rest of it is process control. Once you develop, you rock the process and when you do that, the only real big issue we’ve run into anymore is consistency of material coming in.
DG: I’ve heard, and I want to be careful, and we may have to edit this out, but you mentioned incoming material specs being an issue, the consistency of the material coming in. I have heard that a lot of times the inconsistency in that material is coming in from overseas, let’s just put it that way, and not necessarily Europe.
SK:Far overseas.
DG:Far overseas. Let’s just say far to the East overseas. I guess my question is: Is that still the source of it or are you seeing less issues with that?
SK: Because of what we’ve run and because of the customers that we’ve worked with, historically, that hasn’t been a big problem — not in this market. Although there is high volume, it’s not a tremendous amount of weight. It’s more of the chemistries, the supply chain. We’re hearing it. Part of it is frustrating stop saying supply chain when your guy just didn’t show up and do his job. But, as heat treaters, we will say, we have to be very diligent in contract review. There is mentoring of our younger employees, customers mentoring their younger employees who don’t have the knowledgebase, yet, to understand what they’re actually working with. It’s not a disparaging comment — you learn from making mistakes. You absolutely learn, and that’s experience. So, we’ve seen a talent drain in the last few years. And that is exacerbating the problem.
DG: Right now, you’re doing heat treatment of gun components. Obviously, I’m not going to ask you company names because that wouldn’t be the right thing to do, although it would be fun to do, but it wouldn’t be the right thing to do. But are you pulling in business, let’s say, from pretty much nationwide?
SK: Yes. We don’t get a significant business from overseas. This is due to transportation challenges. Plus, it’s part of our continuous supply chain worth being manufactured, let’s just say, in England, and then ship it to the states to do X, Y and Z, and it ends up being assembled in some state in this country. But as far as countrywide, continent-wide: yes, we’re all over the country.
DG: Do you think the normal guy, like myself (I’m going to classify myself as a normal guy, in this case), would be surprised at the number of gun component manufacturers in this country?
SK: Yes.
DG: Because when I think of gun manufacturers, I’m thinking there are maybe a half dozen to a dozen at most.
SK: Try a different number.
DG: Try a different number — maybe add or multiply that. See, I don’t know!
SK: We’ve been very fortunate that we’ve attended and been at the SHOT show; it’s been held in Las Vegas for the last number of years. You get a better perspective attending that. Now, you have to be approved to attend it, and those who have understand where I’m going with this. There are a number of manufacturers in this country. And we’re not talking about folks who . . . . I’m a family business — we are a family business; we have 45–48 people. We are a small business. I’m talking about companies with hundreds of employees that you’ve never heard of that make components and guns and support that industry.
It’s a significant industry and, by and large, without getting into the politics of this, some of the nicest people we have ever met — truly just generous. I’m talking about even purchasing agents! (For those of you who have dealt with purchasing agents in industries that we will not discuss that have four wheels and an engine!) They’re basically decent people. It’s fascinating.
DG: It kind of rocks your world when a purchasing agent is a real person. It’s like, Oh really, they have heart.
Well, listen Steve, congratulations. It sounds like you guys are doing great work there. I know that you guys do more than guns. Do you care to share, just briefly, what else you do?
Rolls, slitter blades racked, and SS valve seats for vacuum processing Source: Kowalski Heat Treating
SK: Those that know the company, when we say PIA stuff: if it’s a problem, it’s coming to us. Distortion sensitive. We have a significant market in power transmission, clutch plates, brake discs, big round flat things, visually, from three inch in diameter to 50 inches in diameter — that’s our world. You name the market: power transmission, auto . . . . We don’t do much in the aerospace industry; it’s just not something that my people and I want to deal with. Other than that area, medical, nuclear, Department of Defense. We do a significant amount of research and development where folks like you say, “Hey! I have an idea! Can you help us?” and we assist them on the metallurgical heat treat side on building processes. Outdoor power equipment. Basically, if you have a problem, I’ve got 10 guys for you who are incredible at what they do. We just like having problems. I’m telling you how we work: If I can solve your problem, if our team can solve your problem, are you going anywhere else?
DG: Exactly right. Nope, not going to do it.
SK: And we like to try and have fun doing it.
DG: Yes, that’s right. Get the work done and enjoy it if you can.
Steve, listen, I really appreciate you being here, I appreciate you talking to us a little bit about guns and ammo, I guess mostly gun parts. And, again, congratulations, it sounds like you guys are doing well. We appreciate your insights.
SK: It’s a pleasure, an absolute pleasure. Thanks, Doug.
Since February 2021, Heat Treat Today has had the privilege of publishing the Combustion Corner. In each of these columns, John Clarke, technical director at Helios ElectricCorporation, shares his expertise on all things combustion. In this Technical Tuesday, we're taking a moment to review more of the key points from John's columns. As always, we hope this review helps you to be more well informed, and to make better decisions and be happier. Enjoy these five summaries of the second half of the Combustion Corner columns. To view each installment, click the blue heading below.
Process consistency and energy savings are inextricably linked. To lower operating costs and increase process consistency, John Clarke suggests asking three questions: What temperature is my furnace or oven, really? Do I have excessive safety factors built into my process to compensate for not knowing the temperature at the core of the part being heat treated? How much fuel can I save with a shorter cycle?
Reducing natural gas consumption is not the only way heat treaters can save money. Verifying internal furnace pressure, rebuilding door jams, and taking the time to consider if excess air is reducing combustion efficiency are all as good as cashing a check. Maintaining a consistently uniform furnace temperature saves more money than the energy conserved from using less fuel.
"To not invest money on worthwhile projects makes as much sense as not depositing your paycheck."
The biggest question mark in a heat treater’s mind is often, “What will natural gas prices be in the future?” Since we cannot know the answer to that question, what are some things heat treaters can do to prepare for unpredictable natural gas prices? Burner recuperation, using the waste heating exiting the furnace to preheat combustion air, is a tried-and-true method for reducing consumption. Before trying burner recuperation, the following questions need to be asked: How much will it cost? How much can be saved? Can the existing furnace accept the higher flame temperatures?
In this installment of the Combustion Corner, John Clarke takes some time to reassure the heat treating industry of two key facts about the United States' natural gas market:
40% of the electricity in the U.S. is generated using natural gas.
U.S production of natural gas was at al all-time high in 2021 and is rising. The U.S. is the largest producer of natural gas in the world.
With these two facts in mind, John postulates that the U.S. can be sure of a reliable supply of natural gas in the future, but, given the price differential between European and U.S. markets, American heat treaters are likely to see an increase in price per mmBTU.
Saving money is the same as making money. Adjusting the oxygen levels of flue products measured with a handheld combustion analyzer to operate at an optimal percentage may yield more savings than you think. Reducing a non-recuperated burner from 6% oxygen to 3% oxygen garners $17,792 extra a year for the heat treater. A quick solution with a hefty payback rate.
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What makes the North American heat treat industry of 2022 what it is? As with any industry, the heat treating world is made up of the people who now inhabit it and the people who paved the way for them. Let’s take a moment to think about the past and what we owe to the industry giants, those trailblazers who have guided so many. In that spirit, enjoy the life stories of these three Heat TreatLegendsfromHeat TreatToday'sSeptember 2022print edition. After all, the industry is only as good as the people in it.
To listen to the life stories onHeat TreatRadio, click the section headings below.
Lost patents, risking a million dollars, and unleashing an entrepreneurial spirit he didn’t know he had. These are just a few things that characterized Bill Jones’ life.
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“First, you want to do something that you’re happy doing . . . Then, you must be properly prepared for it. You must have enough education to go forward.” So says Bill Jones, CEO of Solar Atmospheres Group of Companies. A self-proclaimed “technocrat,” Bill remembers being interested in technology from an early age. Technology was the “something” Bill was happy doing.
Throughout Bill’s career, his love of technology often led his peers to complain, “You know, Bill, you’re always interested in technology, and you’re not interested in whether you’re making money or losing money.” The complainers may have been right about Bill’s interests, but they were wrong about how much his love of technology would hinder his ability to make money. Today, Bill and his wife Myrt are the sole owners of four successful, family-owned heat treat companies based in North America: Solar Atmospheres, Solar Manufacturing, Magnetic Specialties, and Vacuum Furnace Systems.
"There is nothing that beats hard work and dedication to what you are trying to do." - William Jones
How did Bill go from being simply a technocrat to the owner of multiple businesses? Bill’s answer: work ethic and education. There is no substitute for being willing to put in more than 40 hours a week and to dedicate yourself to your work. But, Bill says, education is also a must: “We, as practical people in the heat treat industry, tend to pooh-pooh education,” and “[the] basis of what we do comes from chemistry. Metallurgy grew out of chemistry. If you don’t have a decent educational background, then you don’t know the basis of where we came from because that’s the basis of where we’re going.”
Armed with his education and his work ethic, Bill began his journey into the world of technology by working with dew point analyzers. At the time, there was no way to continuously monitor dew point or moisture, and Bill’s first project was to produce a dew point analyzer that could measure one to two parts per million. From measuring dew point, Bill moved on to measuring temperature, and this was his introduction into the furnace industry. In 1963, Bill began a career at Abar, where he used his experience designing optical pyrometers to produce thermocouples that could be used at above 4000°F.
At Abar, Bill worked as the equivalent of a chief engineer on a project that he would later characterize as one of the greatest accomplishments of his life: designing a vacuum furnace with a horizontal ring hot zone. When the new furnace started up for the first time, Bill saw what a ring hot zone could do. Bill still remembers the experience: “When I tested that first round hot zone, I did it by myself at night in a plant where I was the only one there. We had a big sight glass in the front of the furnace, and I could see the entire hot zone, the heating element, the heat shield, the ring and so forth, and I was able to measure the temperature and it was [like] ‘WOW. This thing works!’”
True to his technocrat identity, Bill views this furnace as his greatest accomplishment, not the success of starting his own companies. Along with the development of this furnace, Bill helped to develop the graphite hot zone, which later replaced the metal hot zones at Abar. With graphite hot zones, riveting was unnecessary, and the elements could be bolted together with graphite screws and nuts. One of Bill’s greatest regrets in life was not patenting the horizontal ring furnace. “We should have,” Bill says, “but we didn’t know what we had, honestly, and then it got out into the fi eld anyway and we couldn’t patent it.”
Lost patents, however, did not get in Bill’s way. Bill is also proud of the car bottom furnaces built at Solar’s Hermitage location in Western Pennsylvania. Bill remembers the weekly design meetings and running the furnace for the first time. The car bottom furnace was designed to process heavy titanium coils, and Bill was so confident in his work that he insisted on running the furnace for the first time with a million dollars of titanium coils inside. A coworker, Bob Hill, said, “Bill, you’re not going to run the final product first. I think we should make a run with just some scrap steel that we have around.” Bill replied, “No, Bob. I am thoroughly convinced this furnace is going to work and work right.”
Today, Bill and his wife Myrt are the sole owners of three successful, family-owned companies based in North America: Solar Atmospheres, Solar Manufacturing, and Magnetic Specialties.
Bill’s confidence paid off ; the car bottom furnace worked correctly the first time.
Chronicling his experiences, Bill wrote The Golden Nugget: An Entrepreneur Speaks. Bill’s identity as an entrepreneur was a surprise to him. Bill credits Dr. George Bentley with inspiring his entrepreneurial spirit: “Bill, I want to tell you something,” Dr. Bentley said, “I have observed you over the years and I can tell you, you are never going to be happy until you run your own business.” At the time, Bill did not realize the wisdom of the advice, he did not see himself as an entrepreneur. But now, Bill realizes, “Until you’re sitting in the top chair and until you’re making the decisions of winning and losing, you don’t know what it’s all about.”
Entrepreneurship (no matter how unplanned), innovation, valuing education, worth ethic, and above all else, a love of technology all helped Bill Jones along the road to success. And the main motivation? “Well, it’s very simple: Money is not a driving factor in my life or in my wife’s life. Money is not it. You know, the old saying is, when you go to the grave, there’s not going to be a U-Haul behind you.”
What’s the job of a good doctor? First, do no harm. This mantra, combined with Dan Herring’s love of doing good by solving critical problems, made him what he is today: The Heat Treat Doctor®.
The Heat Treat Doctor® has worn many, many hats throughout his more than 50 years in the heat treating industry. He was a metallurgist, a corporate trainee, an international marketing worker, an applications engineer, a technical director, a research and development director, a product manager, a chief engineer, and finally: an entrepreneur, the owner of his own consultancy, The HERRING GROUP, Inc. In Dan’s own words: “You might say that I’ve been chief cook and bottle washer of the industry, if you will.” These various jobs, and the multitude of different responsibilities that went along with them, taught Dan everything he knows today, developed him into The Heat Treat Doctor®, and made him worthy of being a Heat TreatLegend.
Looking back on his success, Dan points first to his parents for helping him to become the best version of himself. Dan grew up with one parent that gave him a love of technology and equipment and with one parent that give him a love for language and writing. Dan’s father, a machinist, was a hands-on worker and “one of the most inventive people that I ever met.” Later, Dan combined the technical skills he learned from his father with his education as an undergraduate in engineering and a graduate student at the Illinois Institute of Technology.
Dan’s mother, a registered nurse, was “an English teacher in disguise.” She gave Dan a love of writing. For over 10 years, Dan authored a monthly column for Industrial Heating. Columns, however, are not the extent of Dan’s writing expertise. He has also authored: Vacuum Heat Treating, Volumes I & II, and Atmosphere Heat Treating, Volumes I & II. These four books are excellent resources for heat treaters, both novices and experienced industry professionals. Dan has written 10 books in total, six of which deal with the heat treating field. Dan is proud of these books because he can share what he knows with others forever, just as others passed knowledge to him.
“I think it’s interesting,” Dan says, “I have had the extremely good fortune of working for two or three people that actually fell in the genius category. These people were absolutely, positively of genius intellects and they worked within the heat treating industry.” During Dan’s time at Lindberg, he met Hobart Wentworth. Wentworth taught Dan the discipline of engineering, taking Dan’s university knowledge into the real world. Also at Lindberg, Dan was introduced to Russ Novy, chief metallurgist. Dan commends Novy for his “infinite patience . . . to tell you what he had learned and explain things and talk about the root cause of things.” When Dan worked at C.I. Hayes, he met Herb Western, a man who holds over 300 patents in the state of Rhode Island. Western showed Dan how to be creative and inventive within the heat treating industry.
Vacuum Heat Treating, Volumes I & II Atmosphere Heat Treating, Volumes I & II (For more information: www.heatreattoday.com/industryresources/books/herring-books)
One of Dan’s greatest accomplishments was establishing The Heat Treat Doctor® brand. “The brand,” Dan says, “has brought heat treating into the forefront of manufacturing, into the forefront of the industry, into the forefront of engineering, that yes, there is something called heat treating and it is a solution to your needs. So, I view the brand as not so much a personal accomplishment but as an industry accomplishment.”
Dan’s love of words gives him a unique skill set. Not only does he understand metallurgy and engineering, but he is also patient enough to explain it and has the communication skills to explain it well.
When it comes to business, Dan’s main rule is: “Be honest . . . be ethical, be fair, try hard, communicate well and have infinite patience. In other words, not everyone understands what you’re saying. You must take the time to explain what you mean to the people you’re dealing with. Although that’s a strange answer on the business side, I think it’s most impactful.” Dan takes pride not only in doing good throughout the industry, but also, like a good doctor, doing as little harm as possible. Helping others with critical problems, getting companies back in operation, and preventing layoffs are events that stand out the most to Dan.
When it comes to life, Dan’s mantra is: Enjoy the moment. “I remember the first day I started to work at Lindberg,” Dan says, “I took the train to work, it was right across the street from the train station, I was walking across the street, I was 21 years old, and I said to myself, ‘Only 44 years to go.’ And I turn around and the 44 years have disappeared like it was yesterday. So, you must enjoy what you do, and you’ll never work a day in your life.”
Dan attributes his success in the industry to the people around him. He points not only to his parents for his success, but also to the “geniuses” he has worked with along the way, and to the industry at large. Speaking of his entry into Heat Treat Legend status, Dan says, “I just want to say that I consider this a distinct privilege to be considered one the Heat TreatLegends. But I’d also like to point out to everyone . . . that no one individual can do it by themselves. So, I’m accepting this accolade, if you will, on behalf of the many men and women who toiled in, what I’m going to call, relative obscurity and who made this industry what it is today. On their behalf, I’m more than willing to be considered one of the Heat TreatLegends.” Spoken like a true legend.
“Happy, happy, happy.” In Suresh Jhawar’s experience, the best way to run a business is to focus on happy employees, happy customers, and happy bottom lines.
What happens when a young man comes to the United States against his parents’ wishes to earn a bachelor’s degree in Engineering? He becomes the sole owner of G-M Enterprises and gets the title of Heat TreatLegend. At least, that is what happened for Suresh Jhawar, a self-proclaimed “average student in India.”
Without the support of his parents, Suresh weighed the odds of coming to America versus studying in Germany or the U.K. and applied for his visa and passport in a library, away from his parents. When Suresh discovered he could earn his degree in half the time with his advanced credit, he chose the United States and boarded a plane, arriving in the States in 1962. At Marquette University in Milwaukee, Suresh went on to earn a master’s degree in Mechanical Engineering and an MBA in Marketing.
Before taking ownership of G-M Enterprises, the two heat treating companies that were most influential for Suresh were Abar and Ipsen. Suresh began his time with Ipsen in 1970 as a project engineer for vacuum furnaces. Suresh was in the top five at Ipsen, and, looking back, he sees himself driving the company in cost savings, product improvement, and customer relationships.
As the assistant to the president at Ipsen, Suresh traveled extensively to Poland to visit a facility for steel milling and annealing silicon steel coils for transformer steel. During this time of heavy travelling both at Ipsen and later at Abar Furnaces — Suresh visited Poland ten times in less than two years — he remembers the difficulty of keeping a healthy work/life balance. But he succeeded most of the time: “[W]hen Andy [Suresh’s son] was getting an award at his high school, I was coming from Europe . . . I missed my connection. Now it became difficult as to how to get to Philadelphia to attend that awards ceremony for my son . . . I went from one airline to another. I got on a plane, reached Philadelphia airport at the time when the program started, but I was at the school at the right moment when Andy’s name was called. I was there!”
Difficult though it may have been, Suresh often succeeded in keeping work and life in balance. At Ipsen, work consisted of many projects, one of which involved helping Ipsen book an order for 10 large car bottom furnaces. While Ipsen’s president handled the commercial aspect of the order, Suresh handled the technical side of things. He had to make sure the company had the right product and the right solution. And the 10 car bottom furnaces — 84 inches wide by 45 inches high by 32 feet long, made in four bolted sections — were indeed the right solution.
“What I believe is ‘happy, happy, happy’: happy employee, happy customer, happy bottom line.” - Suresh Jhawar
It was at the same time as this project that Suresh was also working on Ipsen’s license agreement with Elterma, which later became SECO/WARWICK. Suresh’s work at Ipsen lasts to this day. Without Suresh, Ipsen would have no manufacturing base in India. Suresh enlisted Wessman Engineering as a sales agent for Ipsen, which began Ipsen’s history in India.
Abar was Suresh’s act two. Suresh wanted to run the entire operation, and Abar gave him the opportunity to do this. Under Suresh’s leadership, Abar increased its profit significantly, and Suresh was asked to write a justification for the merger between Ipsen and Abar. At G-M Enterprises, Suresh’s skills were on full display. Suresh entered G-M Enterprises as a partner holding 15% interest. Within a year, Suresh bought out one of the other partners, and later, in 2005, Suresh took full ownership of the company. He changed the official name of the company to Jhawar Industries and continued to do business as G-M Enterprises. When Suresh joined G-M Enterprises, it was a break-even company. By the time he retired, it was doing business all over the world. “I’m pretty sure,” Suresh says, “that we had the highest bottom line in the industry.” In 2005, Suresh hired his wife, Veena Jhawar, as the director of supply chain, enabling him to focus entirely on developing customers and innovating vacuum furnaces. Suresh’s innovation did not stop there as he was also instrumental in developing the MIM furnace. By 2018, G-M Enterprises was a leading supplier to GE from Singapore to Japan and Brazil.
How did he do it?
“What I believe is ‘happy, happy, happy’: happy employee, happy customer, happy bottom line.” When it comes to happy employees, Suresh says, “The most important thing is to treat your employees like you treat yourself. When I worked at G-M, out of any of the other places, I didn’t work as being ‘the boss’ or on a high platform; I worked shoulder to shoulder with them.” In order to be successful, Suresh believes you must respect your employees and reward them for their contribution, and hopefully, they will be loyal to the company.
Loyal employees make for happy customers. Happy customers, in Suresh’s thinking, have to feel they are a critical part of the solution. This was one of G-M Enterprises’ best qualities. If a customer had a problem, someone from G-M would jump on a plane and fix it, attending to the problem first and worrying about the terms later. Listening to what customers actually wanted, rather than simply giving them what the company already had, was a crucial part of building customer loyalty. With these two principles in place — happy employee and happy customer — the bottom line grew happier and happier.
With these two principles in place — happy employee and happy customer — the bottom line grew happier and happier.
Along the way to a happy bottom line, Suresh discovered the importance of meeting deadlines. Suresh remembers showing up to a production control meeting with no drawings in hand and the others in the room laughing at him. Suresh could tell they were thinking, “He puts pressure on us, but he doesn’t do his own job.” And so, Suresh never went home that day, but instead worked through the night. In the morning, he put all the drawings into the hands of the engineering crew. “Meeting deadlines and commitment, to me, is always number one. No excuses . . . That helps you to expect [the same] from other people, [because] when they see you — that you do that — they follow.”
Reminiscing, Suresh remarks, “We always treated our employees as family members and gave them due respect for their contribution.” For Suresh Jhawar, success in business is all about happiness.
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Heat Treat Todaywill be a sponsor for the technology trade fair quartet in Düsseldorf, Germany, and we hope to see you there in June 2023. To learn more about GIFA, METEC, THERMPROCESS, and NEWCAST, check out this interview with Friedrich-Georg Kehrer, global portfolio director at Messe Düsseldorf GmbH, about Messe Düsseldorf’s ecoMetals Campaign.
Friedrich-Georg Kehrer Global Portfolio Director Messe Düsseldorf GmbH
The technology trade fair quartet GIFA, METEC, THERMPROCESS and NEWCAST will again provide a complete overview of the foundry technology and metallurgical sectors from June 12–16, 2023 in Düsseldorf, Germany. Which trend topics will particularly characterize the trade fairs?
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Friedrich-Georg Kehrer: How green are the energy-intensive foundry and steel sectors of industry? How sustainably do they produce and how eco-friendly is their use of materials? These are the crucial questions dominating the agenda and providing ample food for thought at GIFA, METEC, THERMPROCESS and NEWCAST 2023. Tasked with achieving climate neutrality by no later than 2050, these industries face what is probably the biggest transformation in their history. This decisive development will be reflected by the Düsseldorf trade fair quartet: on the one hand, the challenges that the sectors face; on the other hand, the innovations that machinery and plant manufacturers offer to the metallurgical and casting industries worldwide clearly making them part of the solution rather than the problem. Through in-depth exchange with the professional bodies and experts from all stages of the value chain we have identified the following three mega trends:
Sustainability in the sense of energy and resource efficiency, for instance in the form of green steel or green iron as well as the decarbonization of the steel and iron industry using hydrogen as a catalyst – summarized succinctly under the “ecoMetals” motto.
The use of digital technologies in manufacturing, i.e. the buzzword “Industry 4.0” in steel mills and foundries also remains another mega trend.
Also, automotive lightweight construction as well as the latest additive manufacturing processes for steel and metal working continue to play a key role.
With our four trade fairs and the extensive line-up of ancillary events we offer a unique platform worldwide to discuss these important topics.
The buzzword “ecoMetals” is mentioned in connection with GIFA, METEC, THEMPROCESS and NEWCAST time and again. What does it mean and what role does the campaign play in the events?
Friedrich-Georg Kehrer: Messe Düsseldorf’s ecoMetals Campaign forms an integral part of the “Bright World of Metals” and has a long-standing success story. It refers to the ecological path of the casting and metal processing industries and promotes exhibiting companies that invest in innovative, sustainable and economically competitive technologies. Trade visitors can easily identify the award-winning innovations and are guided to the respective exhibitors at GIFA, METEC, THERMPROCESS and NEWCAST by complimentary daily Guided Tours – so-called ecoMetals Trails. Furthermore, these exhibitors are especially highlighted in the respective Internet portals as well as in the catalogue and their exhibition stands are marked. The ecoMetals campaign was already received very well at the previous edition of the trade fair quartet. Our visitors highly appreciated this guidance. I am particularly pleased to see that some of our other capital goods trade fairs such as wire and Tube or decarbXpo have also adopted this concept this year. With this move Messe Düsseldorf also wants to live up to its ecological responsibility and provide the drivers for environment-saving products, production and processes with a special forum.
So the ecoMetals Trails will enable trade visitors to discover “new pathways for value creation” at the trade fairs?
Friedrich-Georg Kehrer: Yes, exactly! The ecoMetals brand focuses on three fields of sustainability: Resources, Innovation and Production and/or Processes. How can raw materials be extracted in a more resource-efficient way and processed more efficiently? What is trending in metal and non-metal recycling? Which new technologies, machines and plants are used to improve the energy and CO2-balance? The sustainability drivers exhibiting at GIFA, METEC, THERMPROCESS and NEWCAST will share their solutions for all of these challenges. At their exhibition stands they will explain how they reduce their carbon footprint at their production sites and merge business with environmental protection. Overcoming these challenges is as important as ever to hold your own against international competition as a valued business partner.
How much does participation in the ecoMetals Trails cost?
Friedrich-Georg Kehrer: Participation in the ecoMetals Trails is free of charge for all visitors. Registrations can be submitted on the respective websites in the run-up to the trade fairs. Of course, those deciding onsite to take part are welcome to join a tour without prior registration.
On September 21 this year the ecoMetals Day will be held as the “Steel Day of the Future” at the Düsseldorf Exhibition Centre. What kind of event is this and how does it relate to the Bright World of Metals?
Friedrich-Georg Kehrer: The ecoMetals Day will be held for the first time, concurrently with glasstec, as part of our new event decarbXpo. The ecoMetals Day will attract the Who’s Who of the steel sector and cover all topics relevant to the technical, economic and ecological transformation of the steel industry in form of unique lectures. These impulses are, of course, also of enormous importance for THERMPROCESS 2023.
Can you already reveal any details regarding registration levels? How are the trade fair preparations going in general?
Friedrich-Georg Kehrer: The preliminary work has been completed successfully, many companies have already registered and the allocation of exhibition space is in full swing. Now the time for finetuning has come and, of course, for the visitor promotion campaigns. Our exhibitors are eager to inspire the trade fair audience at GIFA, METEC, THERMPROCESS and NEWCAST with their technologies and innovations. All renowned companies will be represented in Düsseldorf again plus many new exhibitors taking part for the first time. GIFA, METEC, THERMPROCESS and NEWCAST are the most relevant events for their respective industries; they thrive on personal encounters and the exchange of ideas in this special setting. Everyone is particularly looking forward to this — especially after such a long time!
ThermTech, heat treat service provider in Waukesha, WI, has increased their capabilities to provide services for the medical, aerospace, mining and oil, nuclear, and agricultural industries.
Jason Kupkovits, vice president of Sales & Strategic Direction at the company, commented on that ThermTech will be continuing their 40 years of quality assurance, turnaround time, on-site engineering, and customer service standards.
Ben Gasbarre Executive Vice President of Sales Gasbarre Thermal Processing Systems
Partnering with Gasbarre Thermal Processing Systems, ThermTech significantly increased their normalizing, annealing, stress relieving, tempering, and neutral hardening capacity through the acquisition of three new furnaces. These three furnaces --- now fully operational --- include: a dual zone, direct-fired box austenitizing furnace; a large batch tempering furnace; and an additional tempering furnace. These furnaces are compliant with AMS2750 at different class certifications.
ThermTech has also added two additional vacuum furnaces from Ipsen, USA. The furnaces have dimensions of 36” wide x 36” tall x 48” long with capabilities of quenching up to 6 bars of pressure utilizing nitrogen or argon gas as the quench medium. These large vacuum furnaces are AMS class 3 (+/-15°F) certified capable of AMS2750.
ThermTech added a solution annealing furnace from Williams Industrial Service to give their operational aluminum line additional heat treat capabilities. This line is capable of a sub-15 second transfer to air blast quench, a water quench range of 55°F up to boiling, a sub-7 second transfer to water quench which exceeds AMS 2770/AMS2771 specifications, as well as load thermocouple monitoring during the solution treatment, quenching, and aging.
Daniel Hill, PE Sales Engineer AFC-Holcroft Source: AFC-Holcroft
Another recent acquisition includes a new austempering/marquenching furnace from Michigan based AFC-Holcroft. This furnace can handle a single part racked in the vertical orientation up to 56" long. The working dimension of the furnace is 36" W x 72" L x 56" H and is capable of operating with salt temperatures ranging from 350°F -- 750°F. "The UBQA system is an environmentally friendly ‘green technology,’" commented Dan Hill, sales engineer at AFC-Holcroft, "which can be used to impart resistance to distorting, cracking or warping of heat-treated components.” Applicable processes include marquenching, austempering, and carburizing with additional washing and tempering capacity accompanying the new marquenching/austempering furnace. Installation is expected in early 2023.
The heat treat service provider's long-term strategy is to increase growth in the Midwest and on a national scale. This includes adding more workers and integrating the use of a robotics handling systems, which is expected to be installed in late 2022.
Find heat treating products and services when you search on Heat Treat Buyers Guide.com
Doug Glenn, publisher of Heat Treat Today, returns to the question on the future of hydrogen for heat treaters as he moderates a panel of five industry experts. What are the technological developments since last year and how do heat treaters need to prepare for these developments?
The experts who will give their take on the issue include Joe Wuenning, WS Thermal; Jeff Rafter, Selas Heat Technologies; Justin Dzik, Fives North American Combustion; John Clarke, Helios Electric Corporation; and Perry Stephens, EPRI.
Below, you can watch the video or 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.
Doug Glenn (DG): Well, we’d like to welcome everybody to a second round of Hydrogen Combustion. We’re going to have a discussion about hydrogen combustion here on Heat Treat Radio which is now really a Heat Treat Radio (and video). We’re welcoming back some of the same folks that talked with us from about one year ago.
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I want to do some introductions, reintroductions in most cases, and we’ve got one new participant on the panel this year. So, let’s start with the introductions and then we’re going to jump in. We’ve got about six questions to cover; hopefully we’ll be about 30–45 minutes of discussion on this.
Let’s first introduce John Clarke (if you want to raise your hand just to let everybody know who you are there). This is John Clarke. He is the technical director and owner of Helios Electric Corporation, a Fort Wayne, Indiana-based company that specializes in energy and combustion technologies. John is also a regular columnist for Heat TreatToday, which we appreciate, by the way, and has written 12 articles with our publication in a series called Combustion Corner. So, John, I want to thank you, and welcome.
Next is Justin. Justin is our “newbie” on this one, but not a newbie to the industry — of course! — but to this panel. Justin Dzik from Fives North American Combustion, Inc. is the manager of business development at Fives North America with a special focus in combustion engineering. Justin has written technical articles about Ultra Low NOx combustion technology for the steel industry and is closely involved with spearheading the advent of a thermal process combustion tuning solution that leverages industrial internet of things (IIOT) and Industry 4.0 technology. So, Justin, welcome, glad to have you with us this time.
Next is Jeff Rafter from Selas. Jeff is the VP of sales and marketing for Selas Heat Technology Co., the company being out of Streetsboro, Ohio; Jeff being out of somewhere in the lovely state of Wisconsin. Jeff has a rich history in the combustion industry including many years with Maxon Corporation, 29 years of industry experience in sales, research and development, and marketing, combustion application expertise in process heating, metals, refining and power generation. He also has 11 years of service on the NFPA 86 committee and holds patents for Ultra Low NOx burner design and is an IHEA member, as well.
Next is Perry Stephens. Perry is the principal technical leader for the Electric Power Research Institute (called EPRI) and, among other things, currently leads the End-Use Technical Subcommittee of the Low Carbon Resource Initiative, which is a collaborative effort with GTI Energy, formerly known as Gas Technology Institute and nearly 50 sponsor companies and organizations which is aiming and advancing low carbon fuel pathways on an economywide basis, hopefully towards the achievement of decarbonization. Perry is also an active member of the Industrial Heating Equipment Association (IHEA).
Jeff Rafter Selas Heat Technology Company, LLC
We wanted to bring someone in, as we did last time — Joe Wuenning (Joachim Wuenning) — from Europe. Joe is the president and owner and CEO of WS Thermprocess Technic Gmbh [WS Wärmeprozesstechnik GmbH] in Germany and also WS Thermal Process Technology, Inc., in Elyria, Ohio, here in the States. Joe’s company has been on the cutting edge when it comes to hydrogen combustion, and Joe’s company is also an IHEA member company.
Gentlemen, welcome. Thanks a lot. Let’s just start off.
Jeff Rafter, I’m going to start with you, if you don’t mind. It’s been about a year since we spoke last, so the question is (and I’ll address this to all of you, but I’ll throw this one out to Jeff first): What has changed? In the last 12 months, have we seen any major changes in hydrogen combustion technology application?
Jeff Rafter (JR): I think I would say, probably, that the dominant change over the last 12 months has just been general interest in momentum. We’re now seeing inquiries and interest from a variety of different industries. A lot of people are preparing for the future and starting to think about decarbonization in a bigger sense, and then watching that interest be amplified by geopolitical events, I think, is obviously a later discussion question that we’ll talk about, but we’re now getting to a place where parts of the world sincerely have more motivations. It’s now not just an environmental protection motivation, but we’re also seeing, really, a need to continue operations as fuel supplies, in some parts of the world, have now become called into question.
Dr.-Ing. Joachim G. Wünning President WS Wärmeprozesstechnik GmbH
DG: Let’s go to Joe next and then after Joe we’ll jump over to Perry. Joe, what do you think? Any major changes in the last 12 months?
Joe Wuenning (JW): Of course. Here, we are closer to Ukraine Russian war. Germany is directly, very much dependent on Russian gas and the real fear here for companies is that they have to shut down in the Fall because of gas shortages. So, that intensified, of course, the thinking about the future. One issue which became less important is the price. At the moment, the people think- do we even get gas and don’t think what it costs for it. Before, it was a big discussion if prices would go up by 5% or 10%; now, everybody is happy if they will get it and so, basically, we have no more jobs within Europe where that is not a point of discussion.
What can we do? Some people think about electrifying, of course, but we still produce electricity from gas, so that is not really the solution alone, and we don’t know what the electricity grid will do in the future, so flexibility has become a major player also besides. So, not only hydrogen but can we also go ammonia? Can we do other things? What are the options which keep us independent and doesn’t make us dependent so much on one source as it is now, at the moment?
Perry Stephens Electric Power Research Institute (EPRI)
DG: Let’s go to Perry and then over to Justin and then, John, we’ll finish up with you. Perry, what do you think — the last 12 months?
Perry Stephens (PS): I would echo what Jeff said. I think we’re seeing not only sort of a general greater interest but the leadership of Fortune 500 companies which are global in nature and seeing all of these geopolitical situations occur, wanting to think through stabilizing their future energy supplies and understanding that the impacts of climate are beginning to really push down to their suppliers a desire to decarbonize all of their final energy pathways. So, they’re beginning to make inquiries in terms of how they can change over equipment and what needs to be done.
From a technology standpoint, we’re beginning to understand a bit more what elements of hydrogen combustion or blended hydrogen with natural gas, for example, have impacts on what parts of overall systems and what areas may have significant costs or performance impacts for which we may need to do a bit of additional research, so we’re beginning to understand where those impacts may be, as well. I think, finally, we’re beginning to see some results of research that sort of tells us, on an economy-wide basis, the drivers for demand for hydrogen and sort of under various scenarios how much hydrogen might be needed for various economic sectors including the industrial sector.
Justin Dzik Manager of Business Development Fives North American Combustion Source: Fives North American Combustion
DG: Justin, how about you? Now, you weren’t with us a year ago but if you can take your imagination back to about a year ago, what have you seen change on the hydrogen combustion side of things?
Justin Dzik (JD): Honestly, what we’ve seen is just the growing acceptance across not only just industry but government and society that we need to transition from where we are with natural gas or conventional fuels to lower or zero carbon intensity. So, obviously, depending on where you are in the world, the exact timeline varies, but there is increasing focus on how we get from where we are to where we’ve got to go. Obviously, hydrogen is the purer, noncarbon footprint fuel so that’s obviously the ideal state. We’ve also received an increased amount of inquiries and interest in hydrogen, specifically on combustion equipment, and not only just from industry but from utility companies even here in the states talking about blending fuel and putting hydrogen in the natural gas lines and what effect that has on industry as well as some of the residential implications it might have, going forward, for their users.
DG: John, how about you?
John B. Clarke Technical Director Helios Electric Corporation Source: Helios Electrical Corporation
John Clarke (JC): I believe we’re kind of living through that old Chinese curse — “May we live in interesting times!” — because we have seen disruptions, both on our energy supplies and our energy costs. In the U.S., we were tracking Henry Hub prices approaching $10 and now, all of a sudden then, we had a fire in pre-port and the price of natural gas fell 30%. But I think the long-term trend (and the trends are being recognized by everybody), is that we are in an international market, not only for oil, but for natural gas, as well. I think we’ve seen the effect really come home.
The other thing that’s going on, too, is the price of gasoline and transportation in the U.S. has skyrocketed and we’re now experiencing the kind of prices that Europe has lived with for years and years and years. I think all these factors, these externalities, are going to drive interest in any alternative. Hydrogen, for combustion, but hydrogen also for fuel cells and for automobiles. We’re kind of entering a period where I think our technological focus needs to be “all of the above” and I think there’s an acceptance throughout industry and industry leaders that that’s the path we have to be on to protect our businesses going forward.
DG: So, it seems like the consensus, is, from a year ago, the interest — and to a certain extent some of the technologies is advancing, but at least the interest — is very much being advanced. So, it’s becoming more and more of an issue.
Let’s talk specifically and, Perry, I’m going to address this one to you first if you don’t mind: Have we seen in the last 12 months actually any new applications and/or industries that are aggressively adopting it? There is one that pops to my mind that’s been very obvious.
PS: Probably the one you’re thinking about is the steel industry that has a specific nuance of steel production that huge amounts of fossil fuels, natural gas, cooking coal, are involved in the production of raw steel and so that reduction reaction, hydrogen can serve as a chemical-reducing agent. So, it not only introduces thermal inputs but also serves as a thermochemical-reducing agent to actually remove the oxides from the ore that allow you to liberate pure iron content that eventually becomes steel. Plus, a significant amount of process-related emissions that come from steel production make it a target industry, so they’ve been fairly aggressive, particularly in Europe, with a couple projects where hydrogen is involved. And the fact that, as we grow the use of steel, high-strength steel, and a lot of applications, globally, there will be a need to add new iron units into the system. A lot of steel is now recovered scrap steel that is melted through electric arc furnaces, but we need to add additional iron content. So, direct reduced iron processes are beginning to take a close look at hydrogen as a reducing agent and also for thermal inputs.
Quickly, beyond that, in most industrial settings, there is a lot of mobile equipment, and that mobile equipment uses a variety of diesel, compressed gas, propane and so forth, and those applications have a particularly easily converted to hydrogen type applications because they’re relatively small size and captive space; they compete with electric equipment in that space and so those two technologies will come forward.
"That is a little bit more challenging, but we see no real major problems towards that because, of course, we will not have hydrogen as a cheap fuel tomorrow, but we have to introduce it slowly if we have excess electricity converted to hydrogen and then get into the grid but therefore the burner systems have to be able to handle that — the change in compositions; not only switching but also the change in compositions." - Joe Wuenning, WS Thermal Process Technology
As far as other industries, the petrochemical industry uses a lot of hydrogen — they’re used to it. They’ll continue to look at both liberated hydrogen from process and other sources of hydrogen for their end-product production for process heating as well as inputs into the production of various synthetic fuels and other synthetic products that they make in the petrochemical industry.
So, those are the two — steel and petrochemical — in my view, probably most aggressively looking at hydrogen. Others may have other experience, as well.
DG: Justin, let’s jump over to you next on that question; then, Joe, we’ll go to you after that. So, Justin, new applications? Is there anything of that sort you’ve seen?
JD: Yes, absolutely. To echo what Perry said, obviously, the steel industry with their green steel initiative is really pushing forward. From our experience, a lot of interest is coming from the aluminum industry, as well. We play heavily in the aluminum industry, specifically on the melting side, and some major companies are interested in adopting hydrogen firing, especially the ones coming out of Europe and their interest really comes from what happens when you fire hydrogen fuel, and it interacts with the molten bath. There are a lot of material concerns with hydrogen, right? Not just in aluminum, but in titanium firing, as well. Those types of metals tend to have an affinity for hydrogen which could, obviously, have a detrimental effect on the final product. So, really there’s pilot scale tests, full scale tests, all kind of undertaking right now. Obviously, the focus is in Europe but a lot of European companies have plants in the U.S., so we’re seeing a lot of that kind of drift into our territory here and, obviously, being focused out of the European headquarters.
DG: Joe, how about you?
JW: We see a lot of projects right now are running now in the last 12 months. We have various customers which told us they want to try out, out of whatever their furnace with a hundred burners, so two of them run with hydrogen and see what happens — see what the emissions are, see what the burner life is, do they have varying parts? That is a part we do with many customers. It’s quite inexpensive to just try and see what happens. And then, we have two big research projects where we can do it in a more thorough manner, together with university, really also not only switch to hydrogen but also to see what happens if we switch back and forth. So, if we have hydrogen coming in, it goes to hydrogen, it should automatically adjust without human interference. That is a little bit more challenging, but we see no real major problems towards that because, of course, we will not have hydrogen as a cheap fuel tomorrow, but we have to introduce it slowly if we have excess electricity converted to hydrogen and then get into the grid but therefore the burner systems have to be able to handle that — the change in compositions; not only switching but also the change in compositions.
On the other hand, we are using hydrogen now in our lab for quite some time and the people in the lab, really, they get more and more used to it. I think they think it’s more and more rather the better fuel than natural gas, cleaner fuel the more they work with it, and I think not really too many people are concerned now that it could be a replacement if the hydrogen would be easily available.
"But what we’ve seen in the last 12 months is now a general interest shift and we’re starting to field inquiries and take on demonstration projects and things that we would traditionally consider low-temperature heating: baking applications, foods production, metal finishing. And it tells me that, again, momentum is building." - Jeff Rafter, Selas Heat Technologies
DG: Yes, being easily available is an issue, I’m sure. We’ll talk about that a little bit more.
John, how about you? Any new applications, new industries that are adopting?
JC: The thing I have seen is a little off the core of your question, but I’ve seen a couple of municipalities dealing with some of their distribution challenges, and that I’ve seen in the last year where they recognize that hydrogen is a potential opportunity to save on carbon emissions but what would it take and at what percentages can you introduce what kind of impact will it have on common appliances? That is a trend, too, and I think the middle between the production and the utilization is going to be a serious challenge for us in the U.S. and it’s an impediment if we’re trying to advance the front. You know, we have to advance on all three fronts simultaneously if we’re going to achieve an effective market. I’ve seen some very encouraging work now being considered at the local distribution level.
DG: Yes, I think we talked last time. Maybe it was Jeff Rafter, I can’t remember if you brought it up, about some of the distribution snags that we might see in New England with type of old pipe or something like that- wood pipes or something, I forget what it is.
It’s your shot, Jeff, so you go ahead. Any advances? And you can comment on that if you like.
JR: I guess I would say what’s different is that the dominant pattern over the last couple of years that we’ve seen is primarily most of the interest came from industries that were highly energy intensive which usually travels with a high temperature process. So, it goes without saying that many of the early adopters were glass, steel, other metals. But what we’ve seen in the last 12 months is now a general interest shift and we’re starting to field inquiries and take on demonstration projects and things that we would traditionally consider low-temperature heating: baking applications, foods production, metal finishing. And it tells me that, again, momentum is building.
I think, in general, industries beginning to be comfortable with the concept of decarbonization and low carbon fuels, whether it’s ammonia, whether it's hydrogen, but, again, the recognition is that we’re only going to get so far until we see some more significant advancements in the generation of hydrogen and the distribution of hydrogen. Again, I think that remains probably the largest hill that we have to crest before we really get through some significant decarbonization impacts.
DG: It seem that everybody really loves the concept; it’s just the matter of producing it and getting it where it needs to be.
"[Heat] treaters use a lot of hydrogen as an atmosphere, and they use it chemically rather than as an energy source. So, I think when the price comes down, they will jump very quickly on the use of hydrogen or hydrogen blends for furnace atmospheres to replace endo or nitromethanol atmospheres."
Just a quick question to follow-up on this one before we move on to the next question which, John, I’ll address to you first. But, just real quick, a lightening round here: Has anybody seen any significant application of hydrogen, specifically in heat treat, whether it be a commercial heat treat or a captive heat treat? Jeff, have you seen anything? I don’t know that I have the answer, so I’m just curious — have you seen anything, Jeff?
JR: Nothing specific, and I think I’ll take an attempt at explaining why. I think it’s because so much of the heat treat application is really dominated by commercial heat treaters. I think they all do the bulk of most of the capacity. Where end-use companies do indeed have internal or vertically integrated heat treat, we have some interest but nothing yet in terms of meaningful commercial activity where we’ve seen commitment to projects. A couple of major industrial manufacturers have brought forward projects and studies, but nothing on-line that I’m aware of, at least in our space.
DG: Joe, how about you? Anything in the heat treat specific, just briefly?
JW: In the heat treat industry, like I said, single burners, of course. No complete heat treat shop will switch to hydrogen --- it’s simply too expensive. But we don’t need to switch/convert all operations; we can take one or two burners and see that it works.
DG: Justin, how about you? Anything specifically in heat treat?
JD: No, we haven’t had anything in heat treat, mainly for the reasons, I think, John has already highlighted.
DG: John, how about you? Anything specific you’ve seen in heat treat?
JC: No, but I would like to also point out that our heat treaters use a lot of hydrogen as an atmosphere, and they use it chemically rather than as an energy source. So, I think when the price comes down, they will jump very quickly on the use of hydrogen or hydrogen blends for furnace atmospheres to replace endo or nitromethanol atmospheres.
DG: Joe, did you want to add something?
JW: Just a comment: That makes it of course easier since many of the heat treaters have the hydrogen tank available, making tests is not really getting the hydrogen. It’s more expensive for a little while, but they can run the tests for a week or so and that’s done then pretty easily.
DG: Perry, anything specific in heat treat?
PS: The short answer is no; we’ve not seen or heard of anyone, primarily because of that. There are a lot of inquiries around direct electrification as an alternative but that doesn’t work in every case. There are a number of scenarios where that’s not a viable decarbonization pathway and so we need to continue to pursue this as aggressively as we can, but at this point, that, the market price of hydrogen and, I’ll add, the sort of working out of a reliable supply chain of hydrogen because, right now, tube trucks is probably the only way you could really deliver hydrogen reliably to a remote heat treat shop so there is a supply issue there, as well.
DG: And just to unduly poke fun at Perry, you’re the only guy on here that is allowed to mention electricity and get away with it, okay? The rest of us don’t even like that topic. ~chuckle~
John, I’m going to jump over to you on this question. It may or may not apply to you in this case, but your company: What have you specifically been doing developing, let’s say encouraging, over the last 12 months? This is kind of a time when you can tell people what your company is doing.
JC: As far as technology, nothing like my colleagues on this roundtable. We have spent and spend a good deal of time running economic simulations for major users but we still act as consultants. I wouldn’t say we’re laying the groundwork, but when the economic data can be put in, we’ll be in a position to better and more rapidly provide people good, accurate feedback as to cost of switching and cost of implementation.
DG: I think you and Perry kind of are maybe a little bit more on the consulting side, so it will be interesting to see what Perry has to say. But let’s go to Joe next. Joe, what has your company been doing? Then, Justin, we’ll jump over to you after Joe.
JW: At the moment, we are doing two things: one is installing a bigger ammonia tank because we want to get into using ammonia as a form of indirect hydrogen combustion. Do we need to crack it first? Can we use it directly? How far have to purify it? These are questions we want to resolve and do in-house. That is one thing. And then also to improve our hydrogen supply, we will install an electrolyzer. We have a lot of solar on our roofs. It’s not directly our business to produce hydrogen, but we want to have the knowledge to tell our solar customers- does it make sense to produce your own hydrogen on site or should it come from the pipeline? What are the options here? We want to be prepared for that.
DG: Justin, over to you, and then Perry, then we’ll finish up with Jeff.
"[So] we’ll really be focusing on not only the burners ability to run hydrogen . . . but also we’re going to try to really look at the material impacts that hydrogen has on heating and as well as metallurgy to try to help some of these end-users because obviously this is a huge shift going from natural gas to hydrogen." - Justin Dzik, Fives North American Combustion
JD: As of about two months ago, we just fired hydrogen on our regenerative burners. This was in an effort to supply data for our talk at AISTech in Pittsburgh, back in May, where we sat on a panel about decarb. From that, we are actually in the process of breaking ground on installing a permanent hydrogen facility to supply our lab with hydrogen fuel for all our test furnaces.
From what I’ve been told, we’re looking in aiming at about 10 million BTU an hour as the max capacity, so we’ll really be focusing on not only the burners ability to run hydrogen --- we’ll focus on the markets, obviously steel and aluminum first because those have shown the greatest interest, what burners actually go on those, testing the burners ability to run hydrogen; but also we’re going to try to really look at the material impacts that hydrogen has on heating and as well as metallurgy to try to help some of these end-users because obviously this is a huge shift going from natural gas to hydrogen. So, over the next year, we hope to make significant headway in, obviously, our hydrogen studies in our conventional burners here.
DG: Perry, how about you? What are you seeing?
PS: From a purely industrial perspective, we have a handful of projects that we’re working on now. They are essentially down-selecting the most viable pathways for industrial process heating through alternate energy carriers, whatever those might be. We have sister groups within our low carbon resources initiative that are looking at the production and transportation storage of hydrogen, whether that is the electrolysis of hydrogen from water, whether that happens to be the use of steam methane reformation with a carbon captured scenario associated with that, and we’re looking at the cost and performance of all of those particular pathways.
And looking at that for a couple of different sizes of steam boilers as well as direct combustion which is, I think, the primary focus here, and a variety of different types of furnaces, ovens, heaters and a variety of different types of burner configurations in order to assess cost and performance of those, and then begin to do the technoeconomic analysis to determine where these technologies might compete as we project the cost and delivering storage costs of hydrogen into these locations regionally where these industries may be located. So, we’re doing all of that work to basically circle wagons around the most important research that we need to do going forward.
We’re also involved in an oxy firing project with GTI Energy which is looking at, right now, natural gas but also evaluating oxy firing. Of course, if you electrolyze hydrogen, you liberate a lot of oxygen from water and that oxygen is valuable and can be a very important constituent in oxy firing combustion which has a variety of advantages, whether you do carbon capture at the source or just trying to improve the overall thermal efficiency of the process. Those are some areas that we’re working on right now.
DG: Jeff, how about Selas? What’s been going on the last 12 months or so?
JR: Well, I think the last year has really just been a continued pattern of counseling customers on applications and, in specific, what particular burner styles are appropriate for utilizing hydrogen in different processes. But I will say, the other topic that is starting to garner some of our attention and efforts is thinking forward about codes and standards as an enabler for more of industry to get interested in decarbonization and, realistically, while burning hydrogen is relatively easy, the handling and distribution of hydrogen has yet to really permeate the codes and standards that we use on a daily basis to govern design of products and processes. Again, it’s not unknown; it’s used in other industries for other purposes like heat treating, like refining, but we need to bring that knowledge into our codes and standards and really kind of be the highway for industries and customers to be able to convert without a significant amount of “white sheet of paper” engineering.
"I think the work that the steel industry is doing is interesting from a couple of perspectives. One is: How do you supply huge amounts of hydrogen, at scale, at a cost that is reasonably competitive? So, they’re really challenging that outer envelope in terms of how much hydrogen, and in what manner, it needs to be produced, whether blue hydrogen or green hydrogen, and really pushing forward to ultimately, hopefully, drive the price of hydrogen down, green hydrogen."
DG: Are you still at all involved with the NFPA? Is that the type of standards you’re talking about, like the 86’s and things of that sort?
JR: NFPA 86, obviously 85 you could drive into the boiler’s world, 87 if you go into process heaters.
DG: Are you still involved with that? I know it says you have done that in the past.
JR: No, I am not currently on the committee.
DG: But you’d know enough about what’s going on in those, so that’s good.
A quick question. I don’t know that we need to spend a lot of time of this. Justin, I’m going to start with you on this one. We talked about it earlier, about the steel industry and the fact that they seem to be with steel and/or aluminum, but steel specifically, I guess; they seem to be one of the early adopters, or at least attempting to adopt it. The specific question here is: Do you see what they are doing in the steel industry as having any impact beneficial (and/or otherwise) on the heat treat industry, at all? Is there any obvious connection between what they’re doing and how it might apply to a captive heat treater or potentially a commercial heat treater?
JD: Yes. Obviously you have to a crystal ball to know what the future is, but obviously, I think, as the demand for 100% green steel increases and the green steel producers can push their will down on scope 1, 2, 3 suppliers, you’re going to see all processing steps will need to be decarbonized. That’s the future goal, that’s the future state. So, obviously if you go down far enough in the scopes, obviously that includes processes for heat treatments of steel. Who knows how long that will take, but for sure, that is probably the future path in the next quarter century or so.
DG: John, how about you? Do you see any benefit or any impact in what’s going on in the steel industry on the heat treat? After John, we’ll go to Jeff.
JC: Specifically, in the short-term, no, but it’s like with any technological initiative, often there are unforeseen breakthroughs, unforeseen bits of technology that are developed that are very beneficial. Again, it’s the “known unknown” in technological development — we don’t know what it will be but, from experience, we know it’s there. So, I’m optimistic that something will benefit them, but I can’t tell you what it is.
DG: Jeff, how about you?
JR: Well, I’ll take a little bit of a projective throw at this one and that is I think that experiences in the steel industry will help some types of heat treating, in particular, direct-fired applications like annealing. When we move to atmosphere furnaces, I think you get to a position where the application becomes so unique that the experiences in steel probably don’t translate. So, I think there are a couple of different bodies of transferability, so to say; when we look at what happens in steel or other industries, I think it’s going to application specific.
DG: Perry, what about you? Then we’ll finish up with Joe.
PS: I think the work that the steel industry is doing is interesting from a couple of perspectives. One is: How do you supply huge amounts of hydrogen, at scale, at a cost that is reasonably competitive? So, they’re really challenging that outer envelope in terms of how much hydrogen, and in what manner, it needs to be produced, whether blue hydrogen or green hydrogen, and really pushing forward to ultimately, hopefully, drive the price of hydrogen down, green hydrogen.
They are also, I think, helping us to evaluate what we need to understand about valve trains, other supply components and materials, whether that’s seals, and at pressure, obviously, hydrogen has a little quirk of wanting to embrittle carbon steels that may be used for storage or transport. So, work around how to really pardon the systems such that those risks can be mitigated and understanding what it’s going to cost to convert when we go to higher and higher concentrations of hydrogen, up to 100% hydrogen, as a fuel or reducing agent. So, they’re pushing the envelope; the rest of us will be able to take advantage of what they learn.
DG: So, Joe, I think in Europe, the steel industry is probably a little bit more aggressive than the rest of the world. What are you thinking about what they’re doing there and how it might benefit heat treaters specifically?
JW: I’m very happy about that — that they are moving forward and being proactive. I think it used to be a dirty, complaining, dying industry (the steel industry), and now suddenly they are on the forefront of really changing themselves and really wanting to do that. I think we will, absolutely, also profit from that. We see students coming to apply for work from us because they think that’s the future: to work in that business and, I think, that’s true, but that was different twenty years ago when everybody thought maybe we will have no steel industry in twenty years. It might sound stupid that we will have steel industry, but the steel industry presented themselves as being “go to Gary, Indiana or whatever,” if you don’t think that’s a future industry, but that is changing at the moment, and I am very happy about that.
DG: I would like to start with Joe, actually, we’ll just start with you; let’s reverse the course on this one. Let’s talk about obstacles. Whether it be production of hydrogen, distribution of hydrogen, or other technologies, what do you see being the main obstacles for adoption? And again, if you can tailor comments specifically into heat treat, fine, but I think, to a certain extent, where we see it being done in steel and aluminum then, probably, the obstacles will be very similar for the heat treat market.
Joe, what do you think?
JW: I think, at the moment, of course, it’s uncertainty. The people are a little bit sometimes wait-and-see because nobody knows. Will it be electricity? Will it be widely available for affordable prices? Will it be energy carriers? So, I think, and in general, at the moment, of course, there is a lot of uncertainty. What will happen with China? What will happen here? So, it’s very different. Some people just now are sitting there like a little rabbit and doing nothing; other companies are still active and say and see what their options are. I think we will see a lot of changes into the next decade compared to the past and it will be interesting times.
JW: I think the uncertainty, that is, of course, there is no clear pathway to go; everybody has to make their own decisions.
DG: Perry, how about you? Main obstacles for the adoption of hydrogen?
PS: It’s the big elephant in the room: the price. It has to come down in price at the burner tip to be competitive or else, globally, there has to be some agreement which is very difficult to obtain in terms of, sort of, regional competitiveness and globally economic competitiveness of industries. And so, something has to be done.
We have to continue to pursue how we’re going to produce hydrogen, transport and store it and have it become cost effective at the end-use. There are a number of strategies around how to do that but, obviously, if you’re going to electrolyze it, there’s a lot of work looking at how that could be improved in terms of its overall, final efficiency. That’s the biggest challenge. I think, the other transport and storage attributes can be overcome technically; I think we kind of know how to do that.
There is a big decision, I think, with regard to whether we produce hydrogen centrally and then move it around the world in various modes of transport including pipelines, which is generally the most cost-effective way, or in some cases, do you produce that in situ and then the question of whether or not you use steam methane reformation of a fossil fuel and carbon capture — that’s a policy matter.
I will say this: our first round of studies and sort of bookend scenarios that we’ve looked at for hydrogen production and use economywide suggests that policy matters a lot and whether or now we allow carbon capture and sequestration will make a huge difference in the degree to which hydrogen penetrates economically, markets beyond the very big ones that we’ve talked about. So, if we get into heat treat shops, other end-use applications, economically and transport and buildings, a lot depends on where we end up with carbon policy.
DG: Jeff, how about you? Obstacles?
JR: Well, very similar comments to what Perry had said — it has a lot to do with economics, distribution, and availability. Obviously, the last 12 months has not been a typical economic environment for what we’ve enjoyed for fuel security in the last 40 or 50 years, and I think, at this point, nobody has a crystal ball to determine what the relative price of fuel alternatives is going to look like going forward. Obviously, the hydrogen play is still reasonably new from the perspective that we need better ways to generate hydrogen, ones that could put the fuel on par or near natural gas, and as a real-world example of that is we’ve actually seen a resurgence in interest for firing liquid fuels as an alternative to a nonsecure natural gas supply and why? For the simple reason that they’re transportable without a pipeline. So, it will be interesting, but I think it’s that juncture of economics, supply and distribution that’s really going to be the determinate on where we land 10 or 15 years from now.
DG: John, how about you? Obstacles?
JC: For the heat treat area, I think the transportation. Heat treats, unlike steel mills, unlike petrochemical facilities, tend not to be collocated. The commercial heat treat and the captive heat treat tend to be distributed and they’re used to being able to obtain natural gas from a pipe on the road. So, until we have a means to run more pipe, which is a challenge, it’s a very real challenge, especially if you’re trying to obtain a new right-of-way in the U.S., that’s an extremely lengthy period of time. So, assuming, and I’ll assume for one minute that the cost of production, that issue can be dealt with. I think distribution, very likely, will be a longer-term impediment for heat treat in the U.S., maybe not so much for steel or other applications.
DG: Justin, how about you? Last one here on the obstacles.
JD: Yes, obviously, to just echo everyone else — it’s cost and availability, right? So, cost is like ten times what natural gas is right now so, in availability, like John said, do we have a pipeline that goes around the United States with it, that’s quite difficult, or do we produce at site? And then we have to consider the manufacturing capacity of the electrolyzers and the device if we’re going to do it on site; can that keep up with the demand?
Operationally, the cost. You know, thermal efficiency and process integration — really those things will help bring down the cost of hydrogen. The other industries like steel and aluminum are advocates of heat recovery right now — they employ it with recuperative technology or regenerative. Heat treaters don’t really do that and, I think, that is kind of a need when you’re switching to hydrogen to try to bring the cost close. It’s never going to be equal, but to bring it closer to natural gas, heat recovery is almost a must.
DG: Production and distribution, yes, as somebody said, “it’s cost at the nozzle,” how much is it costing?
If anybody wants to comment on this, fine, otherwise we’ll gloss over it and move on to the last question, but somebody commented and said, “I don’t know if you’ve noticed or not, but three-quarters of the earth is made up of water with two hydrogen and one oxygen, right? I don’t know if you noticed, but the bond between those two things is very, very strong.” It’s very difficult to break the hydrogen away from the oxygen. So, almost anything we do to produce it from that, the most abundant source, it seems like, would be water, would be very, very expensive. Does anybody want to comment on that?
JR: Just one additional thought is that in addition to water being widely available, the other challenge you have to have is you’re typically looking for a relatively clean source of water to run through an electrolyzer, and if you think about just what you see on the news every night, we already have a challenge where many parts of the world are having difficulty coming up with adequate supplies of clean, fresh water. So, desalinization definitely has a play in there, but the abundance of water, or hydrogen being the most abundant element in the universe, really doesn’t solve our problems. There are still a lot of developmental challenges around the generation of hydrogen.
DG: Anyone else care to comment on that before we move on? Joe, go ahead.
JW: Regarding the price, of course, that’s a little relative. We fear the moment the natural gas prices triple and quadrupling, it’s also the hydrogen price has to come down. But if the net/gas price goes up steeply, that will then make them also equal, just at another level, not that it’s what the people want but that could well make it much more attractive sooner natural price gas go up.
DG: It’s all the relative price, you’re correct. Any other comments? I think it’s a good segue into our last question and that is: the disruptions that we’ve seen, geopolitical situations and what impact that’s having on the advancement of hydrogen.
Justin, why don’t we start with you on this one. Any comment on the geopolitical situation, how that’s helping or hurting the current move to hydrogen?
JD: Yes, obviously every day it’s changing, so every day it’s making a different effect. But with the increased upward pressure on fossil fuels due to the geopolitical environment, there are potential cost penalties for changing from fossil fuel to carbon-neutral fuels like hydrogen that may be decreased, obviously. So, the desire to maintain the production capability in the face of fossil fuel shortage may further drive switching to hydrogen — hopefully, it will — or other carbon neutral fuels and obviously or ways to achieve the thermal input needed for the processing steps for all these customers.
DG: Perry, how about you? Any comment on the geopolitical situation?
PS: It’s unpredictable. I think the volatility of fossil fuels is an issue. The attraction that we have, at the moment, for hydrogen is that, ultimately, if we look at the production of green hydrogen, it would come from some renewable source.
Now, that could be biofuels that are hydrocarbon-based that are produced in natural avenues that are carbon-fixing so they’re renewable, but when you look at the green pathway for hydrogen through electrolysis, you’ve got to use electricity and so the attractiveness to that right now is that there are periods of time where we have a lot of excess power and we need to store that; batteries are not a good option for the volumes and timeframes that we want to store that power and so production and storage of hydrogen so that we then can reuse it either directly as combustible fuel somewhere or otherwise. That helps the whole energy system work a little better in terms of periods of higher and lower demand and so, I think, to me, that’s going to be sort of near-term more likely to drive things.
I think the geopolitical situations create a lot of interest and realization that we’ve got to do something, but the changes that are going to have to happen, I don’t think they’re going to happen fast enough to respond to those kinds of shock scenarios. So, this is going to take some time for us to deliver an integrated energy system takes advantages of low-cost power to produce hydrogen pulls together production distribution systems that end up working on a fairly seamless and effective final energy distribution system. So, this is not a quick fix.
DG: John, how about you? Geopolitical situation.
JC: Speaking as an American, our geopolitical concerns differ greatly with our European friends. We produce and export 10% of the natural gas — or attempt to export 10% of the natural gas we produce, so we are actually awash with natural gas while our European friends are not. Even if the instability in Ukraine is settled tomorrow, the question comes up: Can Europe trust Russia, long-term, to be a critical supplier and, arguably, I think you can’t. So, I think there’s going to be a divergence.
But even in the U.S., we have a significant political risk that we have to recognize and that is forming a consensus to put in place the necessary rules and put in place the necessary legislation to enable this transformation because we have yet to form a solid consensus in the U.S. that decarbonization is necessary. There are a lot of, again, I’ll use the term “externalities” at play and in the U.S. we, ourselves, even with all our resources are not yet in a position to form any sort of coherent plan to tackle this initiative. So, I caution people from the political side to keep working on the technology and keep writing your congressman.
DG: Two fronts there. So, Joe, give us the unique perspective from Europe on this. Geopolitically, you’re going to have a little different perspective here.
JW: John already mentioned, of course, we are in a different position because we don’t have our own energy sources and now, I think, we are hurt pretty badly by relying on cheap, Russian natural gas supply. We thought that we would get that forever and very reliably and that’s not the case. So, I think we have to diversify, we have to get more of our own resources, we have to conserve energy, use less, because otherwise we are just dependent — we are not free in our political possibilities if we have to rely on that cheap energy. Of course, to a degree, maybe, that is a little different in the U.S. but being dependent if everybody goes out on the street if the electricity shuts off and the air conditioning cuts down is also a kind of dependency on certain things so no telling for the future. So, I think that dependency on cheap energy is dangerous everywhere. And we should work on that to be here more conservative in using it — using less, using on-site; you can have local tank and there have your own air condition on every roof and not depend on the grid and everything. I think that would be good. We learn the hard way right now, but I think sort of which it wouldn’t hurt for the U.S. to do certain things the same way.
DG: Learn by watching rather than learn by doing, you know?
Jeff, how about you?
JR: Well, I think the current geopolitical situation is a reminder that although we’ve enjoyed five decades of really stable, inexpensive energy supply, it’s never guaranteed. It’s been quite a while since we had this type of market disruption around fuel supplies, but it’s a reminder that fuel supplies and energy really are a worldwide market that are deeply interlinked region to region. So, as we look at potential changes and what’s coming forward, I think we have to give a significant amount of focus to where we can make the most impact and decarbonization, and manufacturing really represents, at least in the United States, about a third of all the natural gas consumption. That means that two-thirds of it is power generation residential building and heat and from that perspective it kind of echoes Joe’s comments that it’s multiple technological advancements and market changes at the same time that are going to drive the initiative forward; it can’t just be heat treating or manufacturing, it has to be a union of multiple technological changes and adoptions at the same time for heat, power, electricity and industrial heating.
DG: That wraps up the initial questions that you all knew about ahead of time, so I’m just going to throw out one more: If there was something we were talking about here and you said, “You know, this is really something important that ought to be said.” Did anything like that jump to your mind? Is there anything that you would say kind of as a concluding or also a “Hey, let’s not forget about this?” Anything come to mind?
PS: I’ll jump in, Doug, just tagging on to what Jeff just said. Just a reminder that our energy systems, our supply of binary energy where the energy comes from and the final end-use systems are interconnected by very complex markets and delivery and storage systems, whether you’re talking about power, natural gas, fossil fuels, other liquid fuels and so forth. Those sources, whether you’re looking at bio sources, have limitations in terms of land use or whether you’re looking at hydrolysis of water, whether that be the cost or the impact on water resources and availability or whether you’re looking at wind and solar- all of them have their positives and their negatives. In the end, the marketplace, with all of these various end uses, there are a lot of societal decisions we’re going to have to make around who gets access to which sources. As an example, aviation fuel is a very difficult one to replace in terms of the liquid fuel because of energy density needed and the need to carry it along with you. How do we ensure that aviation gets the type of fuel at a cost that we can all withstand?
So, whether a lot of competition — not just within our industry that we’re talking about here, but amongst all aspects of the economywide uses of these various fuels, including hydrogen — there will be competitive forces that ultimately will create challenges for where and how we use hydrogen and how we produce it and where the best end-uses of hydrogen, specifically, would be, or other fuels like Joe mentioned- ammonia has its interesting potential areas where it could be applied as a combustible fuel and so forth. We just need to understand that there are complex economics involved in determining to what degree hydrogen may end up being a fuel for industrial furnaces.
DG: Anyone else? Something that needs to be mentioned you might’ve forgot?
JR: I would throw in one other comment. Knowing that the audience, for most of this presentation, is going to be in heat treating, I think perhaps one word of advice would be: hedge your bets. Design in and plan for flexibility. Being linked to one energy source is probably not economically advisable for any manufacturing business at least until markets and geopolitical events settle down.
DG: That’s a good point.
Gentlemen, thanks a lot, I appreciate the update in 12 months. Justin, thank you for joining us this time, I appreciate that.
Since February 2021, Heat Treat Today has had the privilege of publishing the Combustion Corner. In each of these columns, John Clarke, technical director at Helios ElectricCorporation, shares his expertise on all things combustion. In this Technical Tuesday, we're taking a moment to review some of the key points from John's columns. As always, we hope this review helps you to be more well informed, and to make better decisions and be happier. Enjoy these seven summaries of the first half of the Combustion Corner columns. To view each installment, click the blue heading below.
In his inaugural column with us, John Clarke sets up the Combustion Corner column series with a look at the basics of natural gas. What do heat treaters need to know about natural gas supply and demand, availability, pricing, and consumption. Plus, the risks heat treaters should consider when making decisions about maintenance and equipment acquisition.
Excess air is the percent of total air supplied that is more than what is required for stoichiometric or perfect combustion. In heat treating systems, excess air plays many roles, both positive and negative. The perfect mixture of oxygen and gas can be elusive. When it comes to saving money and improving safety, carefully monitoring excess air in fuel-fired systems pays dividends.
Maintain regular inspection and maintenance schedules
Combustion safety is the number one priority for all heat treaters. But, what factors should be considered when all safety considerations are in place? After all, many fire protection standards are designed to protect life and property (as they should be), but not the bottom line. The next priorities for heat treaters are: reduce burner failure and therefore reduce downtime, consider component failure rates when designing or purchasing a system, and maintain regular inspection and maintenance schedules.
Downtime is costly. In order to prevent downtime, heat treaters need to “plan the fix” before the fix is necessary.
Planning the fix entails more than an annual inspection. One way to address shut-down-causing errors before they happen is to carefully examine gas pressure switches; switch contact ratings, location, pressure ratings, and protection of the switch from “bad actors” in the fuel gas are all things to consider.
Pressure switches are either on or off. How can heat treaters use pressure switches to detect a possible failure before it occurs? The simple answer: the methods to analyzing time before shutdown is the heat treater’s crystal ball. Creating predetermined warning bands (time limits, which the pressure switch should not exceed or fall below) and monitoring switch response times within these predetermined times by PLC can give a glimpse into future shutdowns.
The NFPA allows for two arrangements of safety shutoff valves: the simple double block and the double block and vent. Both of these arrangements are appropriate as the last line of defense against a safety issue. How can heat treaters bring safety shutoff valves into compliance with NFPA 86? In this installment of the Combustion Corner, John Clarke clarifies how to comply with this common standard and lists some important considerations for choosing between a simple double block and a double block and vent arrangement.
In this column and the following columns in the series, John revisited the topic of natural gas. Reducing natural gas consumption is the best way to reduce cost. How can heat treaters do this? John suggests that we "optimize our processes, reduce unnecessary air, and contain heat within the furnace and/or capture the energy that leaves our system to preheat work or combustion air."
Find heat treating products and services when you search on Heat Treat Buyers Guide.com
A Pennsylvania heat treat supplier recently shipped and commissioned two power supplies used in a continuous brazing furnace for a tool manufacturing company. The new power supplies, rated 125 kW supply and 100 kW, were designed as direct replacements for a pair of existing, obsolete power supplies that continuously failed.
Find heat treating products and services when you search on Heat Treat Buyers Guide.com
Since February 2021, 
Next is Justin. Justin is our “newbie” on this one, but not a newbie to the industry — of course! — but to this panel. Justin Dzik from Fives North American Combustion, Inc. is the manager of business development at Fives North America with a special focus in combustion engineering. Justin has written technical articles about Ultra Low NOx combustion technology for the steel industry and is closely involved with spearheading the advent of a thermal process combustion tuning solution that leverages industrial internet of things (IIOT) and Industry 4.0 technology. So, Justin, welcome, glad to have you with us this time.
