Heat Treatments, a heat treatment services provider, has added a nitrocarburizing system from a North American based company. The system supports the heat treater’s nitrocarburizing efforts, which include a variety of materials and applications, such as alloy steels, tool steels, and high-speed steels for aluminum extrusion dies.
The NXK series sees the furnace and control panel mounted on an integral platform. The particular NXK-812 model is designed to treat workloads weighing up to 2645 lbs., with measurements of 31.5″ x 47.25″. The system is equipped with process technologies such as Nitreg®-C controlled nitrocarburizing and ONC® post-oxidation.
“We are proud to continue our partnership with Heat Treatments . . . in New Zealand,” said Nikola Dzepina, account executive, Nitrex. “[P]rior installations [have been] in operation between 20-30 years.”
The system was commissioned in the first quarter of 2023.
Find heat treating products and services when you search on Heat Treat Buyers Guide.com
You’ve built your vacuum furnace maintenance program, but still looking for maintenance tips for common issues?
Don Marteeny and Caleb Johnson at SECO/VACUUM Technologies lay out their expert advice to assess your vacuum furnace maintenance issues from all angles. Thanks to Doug Glenn, publisher ofHeat TreatToday, for hosting this interview.
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: With us today is Don Marteeny. Don is from SECO/VACUUM Technologies LLC and is the VP of engineering. Don has a lot of experience in this industry, so his input will be valuable.
Don Marteeny
VP of engineering
SECO/VACUUM Technologies
Also with us is Caleb Johnson who is the field service manager, also for SECO/VACUUM Technologies. Gentlemen, we appreciate you joining us.
We’re just going to jump right in. We’re talking about top vacuum furnace maintenance concerns.
Trouble Reaching Vacuum Levels (01:35)
Doug Glenn: Probably the most dire concerns is: “Dang it, I can’t get this doggone vacuum furnace down to the vacuum levels that I want.” Where do we go? What do we do?
Caleb Johnson: Yes, that is probably one of the more critical problems on a vacuum furnace. There are a lot of issues that would stem from that.
Caleb Johnson
Field Service Manager
SECO/VACUUM Technologies
Source: LinkedIn
One of the first checks I would ask to look at is the vacuum gauge itself. Does the trending look okay? Do we think the gauge is still functioning properly? What does your scaling look like? Since those are electronic items, they do have a life on them. It’s an easy one to rule out, right off the bat.
The next place to check would be your vacuum pumps. Are they functioning okay? Has the oil been changed recently? Is the pump still working well? Just going through some of the basic checks like this can tell us how the furnace is doing.
Doug Glenn: Is it typical that the vacuum gauge will fail slowly over time? Does it start to get off target? Maybe it immediate: “Boom. This thing is just gone.”
Caleb Johnson: I think it can be either way. On the one hand, it could just not read. On our furnaces, they usually fail high. It will just say it’s at atmosphere even though you’re under vacuum. On the other hand, the low level on the vacuum gauge won’t reach as good a vacuum. Maybe the furnace is there, but the gauge doesn’t register that. The gauge itself just starts drifting. So, yes, either way — they are both common.
Check the gauge
Source: Unsplash/Justus Menke
Doug Glenn: Alright. So, the gauge first and then the pump. Was there anything else?
Caleb Johnson: For the pump, I think you could look at the amp draw on it and make sure the motor is still functioning properly — that’s a big one.
Doug Glenn: Yes, good.
Don Marteeny: Another thing that I’ve seen commonly is that a customer is running a process that may, in some way, present some contamination to the furnace. Usually, one of the questions that I ask after that process is, “How long has it been since you have done a cleaning cycle?” By that I mean, having the furnace run a hundred degrees over the process temperature for 8 hours just to basically bake everything out of the insulation.
A further question to ask: Was the furnace open over the weekend? Did somebody accidentally leave it open, didn’t pump it back down, and there’s moisture.
I would expect the first run that there would be problems reaching vacuum. There’s an easy answer to that. Yes, you might not get through the production that day, but you’ve got to put it through a cleaning cycle first. Let it run over night then start back in the morning and see where you are.
Furthermore, this can also apply to the gauge. Sometimes it’s not necessarily that the gauge has failed, but there is some contamination. There are ways to prevent that, like the installation of what we call “a clarifier” — basically a copper tube that allows anything that might be in the environment to condense before it reaches the vacuum gauge.
There are several remedies for these common issues, and we have to go through the list of all of them when this comes up.
Caleb Johnson: I would say, too, that cleaning cycle gives us a baseline because all our vacuum leak checks are specified in a clean, dry, empty furnace. After a burnout, you try to get rid of all that contamination. When the door hasn’t been opened yet, that’s the best time to do a leak-up check and say, “Is any air getting into the furnace?”
A lot of times, you’ll see discoloration on your load or the furnace itself — if you’re getting air or moisture in there — some blue or green colors that allude to that. Now, if the load is off-gassing, maybe that’s a common color that you’re getting, but specifically, if you’re getting air in the furnace, you may see the discoloration. The leak check would show that.
A lot of times we’re specified at 10 microns an hour, and, over time, furnaces might not meet that spec. As you get further and further from that spec, then it’s time to come back and do a helium leak check. Sometimes they’re called “using the mass spectrometer” — we call it a leak detector — but that’s a surefire way to find out exactly where any air might be getting in the furnace.
Doug Glenn: That was my next question on this, before we get off the topic of not being able to reach the vacuum level: Let’s say it’s not the gauge, let’s say it’s not the pump. What are the common areas? The one that jumps to my mind: Did you check the door seal? Is that valid? Are there other places that we can be checking right off if we’re failing the leak-up test? What are the most common places where we’re going to see failure to hit the vacuum levels?
Caleb Johnson: Door seals, obviously, are the number one issue because that’s constantly opened and closed. They might dry out. The seal needs to be constantly cleaned and greased. Dirt could fall in there. That’s definitely one. Also, the furnace is going through heating cycles, so the power feedthroughs, they’ll get hot. As they expand with the heat and contract with the cold, it creates a potential for a leak because those seals are constantly shifting a little bit.
Really, any penetration that goes from outside the furnace into it is a potential for a leak. Looking at what’s going to see the heat; what’s going to move a little bit; and like the door seal — what’s been opened or even if maintenance was done and some valve was replaced or a seal was touched — that’s usually the first thing to go for.
Doug Glenn: That was the other common sense point worth mentioning: If something was replaced in the furnace, especially anything that penetrates the shell, and you weren’t having troubles before that, obviously you want to go check that stuff out.
Don Marteeny: More to that point, we’ve come across a couple times where a valve was replaced, and that valve was, say, on the incoming gas line, maybe nitrogen or argon. All of a sudden, we have a leak, but we can’t find it. We’ve leak checked the entire furnace multiple times and still can’t find a leak.
Well, the next place to look — and it seems illogical — but the next place to look is that valve because that did change. Maybe there’s no outward appearance of any oxidation, but low and behold, there is some nitrogen or argon leaking into the furnace through a valve seep that we didn’t expect. It doesn’t happen all the time, but it does happen. That one is especially frustrating to find because it’s the last place you’ll ever look.
Waterflow alarm (08:49)
Doug Glenn: Let’s say you’ve got a waterflow alarm. What’s the first thing we are looking for?
Don Marteeny: I’ll jump in on that one, Doug. It’s not just a cold-wall furnace because certainly there are atmosphere-style furnaces out there that have water-cooled flanges that do require some water cooling. Many of those passages that feed those flanges or, like we talked about, power feedthroughs are very small.
All of a sudden you look down and say, “Oh, there’s an alarm on one of the power feedthroughs that’s not getting enough water; the temperature is too hot.” Okay, chances are good that there could have been some contamination that was somewhere in the system that is now blocking one of those small holes — and I’m talking a half inch or a quarter inch hole — and we just don’t have the flow that’s expected.
The natural first step is: How long has it been since you’ve cleaned the system? How long has it been since the system has been flushed? Again, it’s going to be something that you don’t typically think of, don’t do that often, but if, for some reason, there has been some exposure to air in the system (and exposure to air will develop and typically promote the growth of bacteria which can cause issues in the system) or just from natural deterioration.
A lot of those systems are steel pipe, and they develop some scale. That scale goes somewhere, and the first place you’ll see it is on the small passages because it blocks the passage.
There are a couple biodegradable descalers, at least, that I’m aware of, available on the market. If you’ve got glycol, that glycol can be pumped out of the system, screened, filtered, and put back in. At the same time, you can purchase a descaler which typically can be mixed with city water, and you basically flush the system. After maybe one or two flushes, you can be fairly confident that you’ve removed a lot of that scale and reintroduced the glycol if you need to or reintroduced the water coolant.
The important thing is that you’ve replaced the rust inhibitor or any other chemical treatments that you think are necessary or you’ve been told are necessary by the equipment manufacturer.
Doug Glenn: On this water-cooling system, what percentage of vacuum furnaces out there have closed-loop cooling systems, as opposed to somebody just running city water through a furnace for cooling?
Caleb Johnson: I think the majority of our customers do have closed-loop, but it also depends on how much equipment they’re cooling. If it’s a single furnace, the best scenario is usually just a closed-loop, small system. But when you have multiple furnaces in a room, then you’re on a much larger system. It takes more cooling power, and it may not be city water they’re running through. It might be an open-looped system or just multifaceted with their stations.
Doug Glenn: It’s been quite a while, and I don’t know if it still happens that you’ve got somebody that’s running a cold-wall vacuum furnace and they’re running city water through it. Soon all you’ve got is just a bunch of sludge and stuff, and you’re not a cold-wall anymore — you’re basically just heating sludge.
Don Marteeny: Yes. City water can be especially challenging, unlike having a glycol mixture with DI water (deionized water) or DI water that you input into the system initially. That city water can be hard, so it has a lot of dissolved solids. It can have organics that can end up causing issues if there’s a certain section of the vessel that doesn’t get the right circulation. All of a sudden you get a settlement of those sediments in the water. There are lots of different challenges that are brought on by using city water.
Caleb Johnson: And heat is an activator, as well, right? So, as it’s trying to pull that heat off, now that’s activating some of the stuff — that’s what causes some of the scale buildup or the bacteria. Making sure that the size of the system is adequate is necessary, as well.
Doug Glenn: On modern-day vacuum furnaces, do they have regular flow monitoring of water? Do you know if water is going through and can you tell, over time, “Hey, my flow is slowing down” — can you see it coming?
[blocktext align="right"]I would recommend if you do a routine check-out of the furnace for maintenance, maybe in the summertime, that’s the time to do it. Flushing the furnace, removing the coolant, etc., is quite an undertaking.[/blocktext]Caleb Johnson: In our furnaces, we use digital indicators. Some furnaces actually show a flow rate, but a majority of them are just like a dial indicator with LEDs. We start with max flow and, over time, those LEDs drop out and show that you’re losing flow. Then, when it drops below the set point, that’s when you get an alarm.
Doug Glenn: You get an alarm and then you’ve got to do all your cleaning out?
Caleb Johnson: Those are on individual circuits, so you can tell, pretty much, which part of the equipment needs washed out.
Doug Glenn: Before we move on to the third one, any rule of thumb on how frequently you think a vacuum furnace should be descaled or flushed out? Let’s say, even if you’re not experiencing trouble, is there a best practice time frame?
Don Marteeny: Typically, Doug, this is a not a two-hour process, right? I would recommend if you do a routine check-out of the furnace for maintenance, maybe in the summertime, that’s the time to do it. Flushing the furnace, removing the coolant, etc., is quite an undertaking.
It also depends on the type of cooling system you have. If it’s truly closed-loop, and like a lot of the systems we work with today, they actually have a nitrogen blanket so there’s very little oxygen in the system. They typically don’t require flushes as frequently. But if the water that’s going through the furnace can be exposed to oxygen, then we should probably think about more frequent flushes because then you’re introducing the potential for oxidation and organic material that can cause issues.
Overtemperature Alarm (15:40)
"Too hot in here"
Source: Unsplash/siora 18
Doug Glenn: Let’s move on to another alarm issue that’s overtemperature. It’s getting too hot here — what do we do?
Caleb Johnson: The overtemperature is a big issue because it’s a critical part of your process, especially when it’s your control thermocouple. Thermocouples have a life, and they can fail in different ways. I think the hope would be that the reading just drops out and shuts everything down. But sometimes it shorts against the jacket, and you have a small break or it’s an erratic reading.
An erratic reading can cause bigger issues because now, maybe, the furnace is running hotter than you think or colder, and you don’t really know there’s an issue. Eventually, it will breach the max temperature and shut things down. If everything’s looking okay on the screen, you don’t really know what’s going on.
Watch your trending, make sure the temperature isn’t erratic (it should be stable), and also measure against your overtemperature controller. We usually have two thermocouples, whether it’s a dual element or two individual ones. You will have some redundancy there, but you can compare numbers to make sure they’re within a few degrees and reading accurately.
Don Marteeny: Aerospace requires more frequent temperature uniformity surveys and system accuracy tests to be Nadcap certified. If you’re outside that realm and don’t have that audited requirement, we recommend at least an annual temperature uniformity survey and SAT.
There are two schools of thought: I can replace the thermocouple before it fails and just do it and say it’s part of doing business, or I will run it until it breaks and deal with the consequences. It’s totally up to you. Some customers do it one way, others will choose the opposite.
Both ways work, it’s just you’ve got to be, as Caleb mentioned, watching it closely. As we all know, with vacuum furnaces, we can’t see what’s going on in the furnaces, so we must rely on instrumentation. If the instrumentation is lying to you, that can cause more grief.
Doug Glenn: Whether you’re replacing those thermocouples in advance as a precautionary step or if you’re waiting, I would assume it has a lot to do with the value of the product that you’re running in the furnace. The higher the value, I assume you’re going to say, “You know what, if I miss this and mess up the product, it’s better to replace that thermocouple.”
Don Marteeny: Right. And how much are you running the furnace? If it’s a 24/7 operation, obviously, if you can get to the 3-month period and you’re starting to see issues, maybe you just say, “from now on, I’m just going to replace it every 3 months.”
Or, if you’re running two to three cycles a week because that’s what you need the furnace for and that satisfies your production, you might get a year out of it and it’s no big deal. But you’re right, if it’s a $1,000 thermocouple and the load in the furnace is $15,000, you really must consider that.
Caleb Johnson: Another thing to check is just visual inspection. The control thermocouples are usually just hanging out there in the air, so if you’re running larger loads, it’s really easy to bump it. Even if you’re running a survey for aims full size of the working area, make sure that it hasn’t gotten bent or even the tip chipped off. If it does get bumped, then maybe you pay extra attention, or replace it as a precautionary measure.
Doug Glenn: It’s safe to say: “Don’t ignore it!”
Caleb Johnson: When it comes to alarms, yes, and don’t power through it either.
Doug Glenn: That could be catastrophic. You don’t want to open the furnace up and have a nice pool of metal!
Furnace Software (21:04)
Doug Glenn: Let’s go on to another issue. This is probably a pretty big category because the question deals with software and software issues. Let’s say you’re having issues with the furnace software. What are some good techniques here?
Don Marteeny: Indeed, software is quite a broad topic. The first thing that we typically look at is, is it operational, meaning is it a controller issue or is it a display issue? A lot of times, we’ll have a customer call to say, “The furnace stopped in cycle, and it won’t finish the cycle and we can’t get it to end cycle.” It turns out, usually when you start investigating, it’s not really a software issue — although it may appear to be — the software is actually doing its job. There is some underlying mechanical issue that we have to find.
As I mentioned earlier, we can’t see in the vacuum furnace when it’s running, so you have to really dig deeply sometimes to figure out what is actually happening. I think a lot of times we tend to blame the software, but that isn’t always the case.
That being said, let’s take a step back to the aforementioned display. These are Windows machines, quite frequently, and that’s a good thing because that means we can communicate with the rest of our network in any facility.
However, we all know, too, that Microsoft comes with its own set of frustrations, at times. Those obviously aren’t exempt from the display. Whether or not to update the host computer is a topic that I would highly recommend you discuss with the manufacturer. Updates can sometimes cause headaches because Microsoft is changing things in the background.
Maybe you have another manufacturer’s computer that’s not Windows-based. I would definitely talk to that manufacturer at that point. From my experience, most are typically Windows-based, and the interplay between Microsoft and the manufacturer is very important. The manufacturer of the equipment should be telling you how to handle that process.
Be careful. Most furnaces now have a LAN or local area network, so all the components are communicating via ethernet or PROFINET. Often, customers want to extract data from the equipment, which is fine, but make sure that you discuss how to do that with the equipment manufacturer. We don’t want to interfere with the addressing in that LAN. That will cause issues immediately if the equipment isn’t communicating, within that network, to each other.
Back to the beginning, it is always well-advised to look at what the equipment is telling you, what the alarms are, what the software is telling you. Then take a step back and say, “Ok, what else is going on in the furnace?”
Again, the goal, at least to the equipment manufacturer, is that we’re designing the software to help diagnose. Is it always spot-on? No. It’s still a machine. It still can have irregularities, or maybe we just didn’t think of all the scenarios. We do our best, but we don’t always catch everything.
It’s a matter of stepping back and looking at the situation. Of course, if you can’t find it, that’s when we, or any other manufacturer, can step in and say, “Hey, in this scenario, you need to go look at these items.”
Caleb Johnson: Don was touching on software glitches, but the other thing is maybe you’re losing data. It may be a hardware issue with the computer, as well. A lot of these industrial PCs are pretty robust, and they outlive the Windows operating system. You need to check if it’s still supported by Windows, or if your hard drive is full. Because we collect trend data on our computer, there are files that will start to fill up the hard drive. Once it’s out of space, then the computer doesn’t know where to put stuff. It will start glitching and having issues. That’s another thing to check.
Doug Glenn: Alright guys, thanks. That was the top four. What I want to do now is go into the “rapid fire round.” I’m going to give you probably four to five additional items. We don’t want to go into a lot of depth on these, and we’ll see how quickly we can run down through these.
Hot Zone Replacement (26:04)
Doug Glenn: The first one is this: When do I know that it’s time to reline and/or replace my hot zone?
Caleb Johnson: I think the quick answer would be a uniformity survey. Are you still uniform within your working area? Are you within the calibration, or do you have hot spots and cold spots? Another thing to check would be the energy usage for the hot zone for the heating elements. Are you pulling more power because you’re losing more heat? As the insulation erodes away, then the heat starts escaping out the hot zone area.
Doug Glenn: Any validity just to looking at it?
Caleb Johnson: I’d say you can see the erosion quickly. A lot of the seams where the insulation meets each other will start to become a crevice.
Discolored Parts (27:02)
"Severe discoloration of stainless steel parts and fixturing discolored by a water leak."
Source: Dan Herring, "The Heat Treat Doctor"
Doug Glenn: This is fairly typical. We mentioned it here earlier: I’m getting discolored parts. What am I looking for?
Don Marteeny: Discolored parts are a common complaint. “Hey, I was fine last week and now, all of a sudden, it’s coming out looking like a rainbow.” It typically depends on the material being treated, but colors such as rainbow are oxidation of some sort. In a short answer — it’s a leak check. Have you done a leak test lately? What is the leak-up rate? Has it changed? That’s the first place to start.
Doug Glenn: I have also heard: If you’re running a variety of different parts or different items/materials through your furnace, you’ve got to be careful that the previous load may have deposited some sort of material on a cold spot in the furnace. Then, when you heat it back up again, it can react with the current load. Is there validity to that one?
Caleb Johnson: Yes, if you’re running parts that have coolant or cut-in oil or something, then that’s stuff that off-gases. If you run a high specialty metal that needs pure air, and maybe it’s a higher temperature too, then all of that is off-gassing. Normally if you’re running a special load like that, you should look at running a cleaning cycle beforehand to ensure that there is nothing in an off-gas from the previous load.
Door Seals (28:36)
Doug Glenn: We talked about replacing the hot zone. How about replacement of door seals?
Caleb Johnson: If it hasn’t been greased regularly or if it’s old, it will start to crack and split. Just look at the condition of the door seal and the seam, too, because a lot of times they’re glued together at a seam. If that seam starts splitting apart, that can introduce a leak. It’s time to get it replaced.
Doug Glenn: Basically perform a mechanical inspection, unless you’re getting leak-up. Then if you can isolate that the door seal is the issue, then obviously it’s got to be replaced.
This is probably “Vacuum Furnace 101”: Every time you’re closing it, you should be wiping down the seal and the main, right? Is that a good practice?
Caleb Johnson: Yes. And you don’t always have to clean it, clean it, but even just wiping it to make sure that the grease didn’t catch a lot of dirt in there and is still lubricating the seal.
Doug Glenn: Two more: Let’s say you’re getting the strange black spots or black marks on the inside of the furnace, typically around heating elements and/or feedthroughs and things of that sort. What causes that?
Don Marteeny: Back to that watching the power consumption. Some of the newer furnaces are equipped with gauges that monitor power, current, etc. If you go back and look at the trends and see a lot of current spikes, that’s a surefire indication of arcing. If you open the furnace and see black marks, what’s happening is that that carbon graphite insulation is being destroyed from an electrical arc.
The next thing to ask after that is are the insulators still in place? Have they been contaminated with something that is now preventing them from being a good electrical insulator? The other thing that comes up once in a while is what is the environment like in the furnace? Are you introducing a gas that could be creating a short, a path to ground for the electricity passing through the heating elements? Those are all some things to consider.
Doug Glenn: If you’ve got black marks in the furnace, more than likely you’re having an arc party in there when the door is closed.
Caleb Johnson: Yes. Make sure your heating element hardware is tight because they expand with the heat, so they will start to loosen up. You want to do periodic inspections to make sure that all the hardware is still tight.
High Velocity Fans (31:19)
"We're pushing those fan motors pretty hard during quench."
Source: LinkedIn/Daniel Dudar
Doug Glenn: A lot of vacuum furnaces have high pressure gas quenching. There are some pretty big fans in there. Is there an A-#1 thing we need to be thinking about when we talk about high velocity fans and things of that sort? What are our concerns there?
Don Marteeny: There are a couple different things to be aware of: Number one, when they’re in operation, most of the equipment has a failsafe to keep it from, say, drawing too much current for too long a time and overheating.
We’re pushing those fan motors pretty hard during quench, so the wear during that period is very high. Over time, of course, things like bearings are going to be a concern because they don’t always run for that long. When they are running, they’re running at 100/110%. We’ve got to keep that in mind.
The next thing to consider is how they’re cooled. It depends on the manufacturer. Some are still a fan-cooled motor inside, so they are still relying on gas cooling. It’s got to be kept clean, so that the cooling rate is correct. In our case, we’re water cooling them. We just have to maintain water flow, so we’re back to that conversation. But those, I think, would be a couple of the key things.
Maybe Caleb can expand on some of the erosion that can happen in the hot zone as a result of high velocity/high pressure quench.
Caleb Johnson: As it erodes especially, and creates air leaks, then that air forges its path through there and makes it worse and worse. If you start to see erosion to the point where you think air is getting through, you’re going to want to try and remedy that whether by replacing the insulation or even a short-term patch until you get a new hot zone.
Doug Glenn: You’re talking about erosion and you’re talking about where the high-pressure gas is actually eroding the, let’s say, graphite or whatever, so that now you’re exposing the shell of the furnace.
Caleb Johnson: The rollup for the hot zone, yes.
Another thing you mentioned is high pressure. We put a lot of pressure in there, and it’s high velocity. If you have small parts, depending on the direction of flow, you want to make sure smaller parts fix nice because if they blow off your fixturing, they can cause damage within the hot zone.
Don Marteeny: One other point to that, too, is the heat exchanger. We typically don’t think about the heat exchanger, but it’s actually doing a lot of the work in that process. Over time, typically there are rather densely packed fins in those heat exchangers to achieve the amount of heat transfer that’s required for the process, and they can get contaminated, as well. Periodically, it’s not a bad idea — certainly if you’re replacing a hot zone — to clean that heat exchanger.
Doug Glenn: Clean and/or replace. Excellent.
Guys, thanks so much. I really appreciate your expertise. Thanks very much for being with us and sharing your expert knowledge and field experience.
Caleb Johnson: Thank you, Doug.
Don Marteeny: Thank you, Doug.
About the experts:
Don Marteeny has been vice president of Engineering for SECO/VACUUM for over five years. He is a licensed professional engineer and has been a leader at the company over the last several years filling project management and engineering leadership responsibilities. Don is a member of Heat Treat Today's 40 Under 40 Class of 2021.
Caleb Johnson has worked as a field service engineer for SECO/VACUUM for several years before transitioning to field service manager. He now puts his knowledge of vacuum furnaces to good use by directing and assisting the Field Service Team, as well as by providing technical support to customers.
If you’d like to get in contact with Don or Caleb, go to www.secovacusa.com.
A software system was installed at Allied Locke in Dixon, Illinois, to assist heat treat processing by providing continuous data logging and access to both real time and historical data. The system provides communication with 6 batch IQ furnaces.
This SuperDATA system, from Super Systems Inc., is the first phase of a multi-phase project, with future expansions planned for tempers, endothermic generators, and CAN-ENG mesh belt furnace lines. SuperDATA contains a communication and data logging module, a visualization module and a trending module. The system will aid Allied Locke, who produces for these sectors: agricultural chain, precision roller chain, industrial chain, sprockets, and environmental products.
Find heat treating products and services when you search on Heat Treat Buyers Guide.com
Heat Treat Boot Camp, an event ofHeat Treat Todayprovides basic training to those new to or inquisitive about the North American heat treat industry. From a technical perspective, the event provides an explanation of thermal processes and materials so that non-technical people can understand.
This Technical Tuesday original content piece provides a list of some of the content that will be covered in the sessions being offered this September 18-20 in Pittsburgh, Pennsylvania.
Introduction
Technical session with Doug Glenn Publisher and Founder Heat Treat Today Source: Heat Treat Today
The event kicks off with a welcome reception on Monday evening, September 18, at the Doubletree by Hilton Hotel & Suites in downtown Pittsburgh. Coincidently, this is the same evening that the Pittsburgh Steelers have a home game against the Cleveland Browns. The hotel should be busy with activity since it is located quite near the stadium.
Day 1: Technical Presentation on Heat Treat Basics
On Tuesday, September 19th, the technical portion of the event kicks off with a presentation on Heat, Markets, and End Products. This presentation addresses what is heat treating and why you should care. It delves into the reasons why we heat treat and covers properties like strength, toughness/softness, durability, flexibility, corrosion resistance, heat resistance, wear & friction resistance, as well as biocompatibility.
Technical session with Thomas Wingens Owner, Founder, President WINGENS LLC Source: Heat Treat Today
The session also covers the three sources of heat typically found in industrial processes, how heat is measured, and how it is transferred. A discussion about some of the major markets in which heat treating is used. Products being heated and the processes being used are briefly covered.
Day 1: Technical Presentation on Processes and Materials
The next session on Tuesday, September 19, goes a bit more technical to cover some of the processes performed and materials treated. Processes like annealing, tempering, stress relieving, hardening (both surface and through), homogenizing, normalizing, nitriding, and carburizing to name a few are covered in such a way that it is understandable for non-technical attendees.
Day 1: In-depth Presentation on Equipment Used in Heat Treating
Following lunch on this first day, the group takes a whirlwind tour of the different types of heat treating equipment, components, and supplies used in the heat treat industry along with a brief discussion of the high-heat materials needed to construct the equipment. Some of the specific topics covered include air & atmosphere furnace systems, vacuum furnace systems, induction heating equipment, heat sources including burner, heating elements, and induction power supplies, heat treating control systems including instrumentation, recorders, and controllers, as well as alloys and fabrications, ceramics, refractories, and insulations, quench media, as well as materials characterization & testing equipment. There is a huge amount of basic information covered in this session, preparing the attendee to understand enough about each system to recognize where each fits into the heat processing universe.
Day 1: Field Trip to Local Highlight
Atop Mt. Washington after riding the Duquesne Incline Source: Heat Treat Today
The final session on the first day digs deeper into processes and materials and covers things like the types of steels, aluminum, and other nonferrous metals and how they are thermally processed.
In the evening on the first day, the group takes a trip to the famous Duquesne Incline, which is an historic Pittsburgh icon, and the evening ends with a group dinner.
Day 2: Industry Movers and Shakers
The second day is only a half-day in classes followed by an off-site plant tour — this year of Penna Flame in Zelienople, Pennsylvania, one of western Pennsylvania’s leading commercial heat treaters and one of the nation’s leading flame hardening job shops. The day starts, however, with a discussion of heat treat “players” — suppliers to the heat treat industry, including furnace and induction heating equipment manufactures, burner and heating element suppliers, on-site and industrial gas suppliers, control system and instrumentation manufacturers, insulation providers including both metal, graphite, and ceramic insulations, alloy and fabrication companies, as well as cooling systems and quench suppliers, and materials characterization & testing equipment manufacturing companies.
Day 2: The Latest in Heat Treating and Off-Site Plant Tour
Networking and learning from each other Source: Heat Treat Today
The last two sessions before lunch and the plant tour include a discussion of some of the newest developments and innovations including 3D printing and hot isostatic pressing, as well as AI and sensor and instrumentation advances and a brisk discussion of other industry resources such as associations, institutes, and societies, media outlets, trades shows, training programs, etc.
The standard Boot Camp ends after lunch on the second day, September 20th, unless you’ve signed up for the plant tour of Penna Flame which is located less than one hour north of Pittsburgh in scenic Zelienople, Pennsylvania. Owners Jim, Michael, and Andrew of will greet the participants and give them an informative tour of their third-generation commercial heat treating shop which specializes in flame hardening. The company has also invested significantly in robotic heat treatment equipment and is well worth the trip. Participants should be back to the host hotel no later than 6:00 on Wednesday, September 20th. The heat treat shop tour costs an extra $95 dollars.
Learn More/Register
In 2022, over 30 attendees participated with positive reviews from nearly all. For more information on the 2023 event and to register, visit www.heattreatbootcamp.com. Early Bird registration ends on July 31st, and final registration closes on September 15.
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Generally, electric power consumption is insidious, because it is not seen and is not considered enough by operating personnel. Uncover sources of power consumption at a typical heat treat plant and ways to conserve it.
This column is written by William Jones, CEO and founder/owner of Solar Atmospheres Group of Companies, and Roger A. Jones, CEO Emeritus at Solar Atmospheres, Souderton, PA, and appeared in Heat TreatToday’s June 2023 Heat Treat Buyers Guide print edition.
If you have suggestions for topics you’d like to see in the future, please email Bethany@heattreattoday.com.
William Jones CEO and Founder/Owner, Solar Atmospheres
Generally, electric power consumption is insidious, because it is not seen and is not considered enough by operating personnel. The following is a summary of power consumed in a typical heat treat plant along with several ways to conserve power (and money) in operating costs.
Electric Motors
Roger Jones
CEO Emeritus, Solar Atmospheres, Souderton, PA
Electric motors are prolific throughout a heat treat plant. Some areas where they would be found include:
Water recirculation pumps for cooling purposes
Vacuum pumps
Circulation pumps for oil used in quench tanks
Fans
Quench motors
High Vacuum Diffusion Pumps
High vacuum diffusion pumps operate with no noise, which adds to the insidious nature of their power consumption; operating costs for these pumps are more or less “out of sight.” To ensure diffusion pumps are not increasing costs, confirm that all diffusion pumps are set to run on the ConserVac® settings with full power (all three phases on) during high vacuum cycle and partial pressure cycles running on half power (one or two phases off). When possible, turn off/ shut down the diffusion pump.
Variable speeds of gas blowers can decrease power consumption, especially at the end of a cooling cycle when the heat of compression is noticeable. To do this, program all quench cycles to shut down the blower at the lower temperature as required on the work thermocouples (i.e., 125°F) and do not run blowers for excess time.
Building/Office Lighting, AC, and Heating
There’s more to saving than just focusing on vacuum equipment. Consider the following list of ways to reduce everyday power consumption:
Turn off all office and shop lights when not needed, except for night lights. Make sure all office lights are off during non-working hours and weekends.
Use newer, high efficiency type building lights.
Program office heating and air conditioning for setback, like office lighting.
Lesson to be learned: turn off any electric motor or light whenever it is not in operation.
Costs of Running Electric Motors @ 10 cents/KWh
Furnace Heating Rate
No furnace should be heated any faster than 15°F to 30°F/minute or 900°F to 1800°F/hour, unless specific instructions mandate otherwise.
Scheduling and Power Demand
Understanding the utility company, peak times for electricity usage, and scheduling appropriately can decrease energy consumption and cost. The following are a few suggestions to direct thinking around scheduling and power demand:
Utility company provides an electric power meter for kWh and demand kVA
Meter contains a power demand register
Record of electric power usage over a specific time increment
Instantaneous demand peak recorded each month
Result is the total kW hours registered in one part of the bill and the second part of the bill is kW electrical power demand
Ideal situation: instantaneous power demand would be flat with no demand peaks for the month, but this is not the norm
Batch type electric furnaces can produce major demand peaks:
Major electric power savings are possible if equipment can be controlled so the peak demands can be staged, i.e., over several furnaces
Schedule heavy production cycles to “off peak hours” usually during the evening, i.e., after 6 pm to 8 pm
Some utility companies will not penalize for the demand factor during “off peak hours”
Electric furnaces that operate with “on/off” control using electric contactors are offenders
The furnace will call for full power in the “on mode”
When temperature reaches the set point, power will be completely turned off
Electric power can easily be peaked if several batch furnaces operate in this mode together
Solution: replace the electric on/off contactors with SCR (silicon controlled rectifier) power supplies
SCR controllers will provide a proportional power control, minimizing peaked power demand
Operating Costs for Diffusion Pumps, Varian Diffusion Pumps
Power Factor Conclusions
It is important to be aware that:
Power factor can significantly affect the electric power bill if the electric utility charges a penalty for operating at power factor less than unity or bills in kVA rather than kW.
Electric furnaces that operate with resistance heating elements connected directly across the power line, or incandescent lighting in the plant operate at near unity power factor.
Utility companies penalize users in different ways for power factor and penalties vary by location.
Motors will have an average power factor of 0.8%.
Furnace power supplies will have variable power factor depending on loading, averaging about 0.65.
In Summary
There are many ways to conserve dollars in any ongoing manufacturing or heat treating plant. Knowing what — and how — power is consumed in heat treat departments helps operators identify areas to conserve energy in vacuum processing and also in day-to-day operations. Other than “turning off the lights,” many other opportunities are available to operating personnel as outlined above.
We’re addressing problems our readers operating older equipment face: Does your safety logic measure up?
This column is a Combustion Corner feature written by John Clarke, technical director at Helios Electric Corporation, and appeared in Heat Treat Today’sJune 2023 Heat Treat Buyers Guide print edition.
If you have suggestions for topics you’d like John to explore in the future, please email Bethany@heattreattoday.com.
John B. Clarke Technical Director Helios Electric Corporation Source: Helios Electric Corporation
This month we will break temporarily from our discussion of radiant tubes systems to address a problem faced by our readers who operate older equipment. Does your safety logic measure up? Have you availed yourself of the latest thoughts about how to best construct a safe system?
The National Fire Protection Association (NFPA) publishes various codes and standards to guide the design of heat process equipment. These codes and standards are under constant review by experts in the field and are updated regularly. The latest versions of NFPA 85, 86, 87, and others are readily available for download at nfpa.org/Codes-and-Standards for about a hundred dollars. The investment in reviewing new versions of critical standards provides valuable insight into the thinking of experienced professionals who apply their ongoing experience as they seek to make our combustion equipment ever safer.
The standards above are generally prescriptive — in that they specify devices and locations, but they also teach the reason behind specific requirements if the reader slows down and thinks logically. An example of this is the requirement in NFPA 86 that states the motor starter which drives the combustion air blower (or other critical devices) be included in the interlock string. If the blower motor pulls too much current, the motor starter’s overload relays trip, shutting off the combustion air blower. A fuel rich condition is prevented because as soon as the blower trips, the interlock string is interrupted and the shutoff valves close, preventing any further fuel gas from being introduced to the system. The code also specifies that a low combustion air pressure switch (or draft switch) be applied; but these devices take time to react to the failure, and with safety logic, the sooner a system is rendered safe, the better.
Monitoring the motor starter and the combustion air pressure switch are on the prescriptive side of the standard, but let us think a bit more about this requirement. Loss of the combustion blower is a critical failure. Are there other failures that can shut off the blower that would not be indicated by the auxiliary contact on the motor starter? If the motor fuses were to blow, or a line of sight disconnect were to be opened, would the interlock detect this failure? What can I do to detect these conditions? Perhaps it would be appropriate to monitor not only the contact on the starter, but the current pulled by the motor using some type of current relay?
The safeties that were installed on my system were good enough when it was manufactured in 1990, why upgrade them now? That is a fair question, but one of those questions that is best answered with another question. Has technology advanced in the last 30 years? Have we gained experience, learned from our mistakes and successes? The answer is yes.
So why not avail yourself of the experience learned by the professionals that volunteer their time to ensure our codes and standards encompass their collective experience? Your assignment is to purchase and download the latest version of the applicable codes or standards and take the time to review them. The reading is pretty dry, but the payoff can be extremely beneficial.
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A vacuum furnace recently shipped to a U.S.-based aerospace fastener manufacturer. The furnace will be primarily used to age-harden various fasteners of high strength alloys used in the aerospace industry.
This is the second Model HFL-5748-2IQ furnace for this manufacturer. Like the first furnace, the new furnace features a graphite insulated hot zone of 36” x 36” x 48” deep with a weight capacity of 5,000 lbs., a maximum operating temperature of 2400°F, and a 100 HP quench motor. The control system was customized to interface with the customer’s in-house automation system for recipe control and data acquisition.
“Our customer needed additional furnace capacity to keep up with demand,” commented Jason Davidson, regional sales manager, Solar Manufacturing.
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Discover expert tips, tricks, and resources for sustainable heat treating methods Heat TreatToday’srecent series. And, if you’re looking for tips on combustion, controls systems, or induction in general, you’ll find that too! Part 2, today’s tips, digs into energy and electricity. We’ve added another resource towards the end of today’s post to further enrich your knowledge of induction heating.
This Technical Tuesday article is compiled from tips in Heat TreatToday’sMay Focus on Sustainable Heat Treat Technologiesprint edition. If you have any tips of your own about induction and sustainability, our editors would be interested in sharing them online at www.heattreattoday.com. Email Bethany Leone at bethany@heattreattoday.com with your own ideas!
1. Maximizing Energy Efficiency of Vacuum Furnaces
Contact us with your Reader Feedback!
The use of AC to DC transformers is an energy-efficient innovation that can significantly lower energy consumption of the heating system. Typically, a system uses alternating current as the primary source, which fluctuates output during each half cycle. Using AC to DC transformers limits these fluctuations, reducing the amount of energy used. Furthermore, transformers operate at optimal efficiency when under a reduced load – i.e., less than 70% output in steady-state heating – rather than ramping up to the full operating temperature. Another advantage of the DC-type transformer is that its operating power factor is very close to 1.0, which lowers the utility company’s calculation of peak demand surcharges
Try power feedback for your electric heating elements. Power feedback is ideal for variable resistance heating elements. Kilowatts are used as the unit of control, rather than just current or voltage.
Conserving energy is not only good for the environment, but it can mean more money in your pocket and less downtime. Here are three tips to improve furnace efficiency with diagnostic technology:
Do you have tight and secure terminal connections? Poorly connected power cables waste electricity and can cause fires. An SCR power controller monitors terminal temperature changes and will alert you before failures happen. It also monitors heat sink temperatures and ensures the control’s cooling fan is working properly.
Do you have a heater-break alarm? Heating zones typically have multiple heating elements, wired in parallel. A broken element is difficult to detect and will impact the heater’s circuit, reducing the power of the process. This can waste energy and affect product quality. A heater-break alarm will alert you to a failing heater circuit.
Do you pay high electricity bills? You could benefit from a factory load management system. It’s now possible to limit peak current loads and power usage across your factory and multiple furnaces. These systems communicate by sharing important power-demand information and providing more effective power distribution.
A connected and automated factory network saves electricity and improves operational efficiency by establishing powerful furnace management systems.
After absorbing today’s tips, you may want to take one step farther to read up on induction heating. Take a look at “Why Induction Heating is a Green Technology” to help broaden the horizon.
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Advanced Heat Treat Corp. (AHT) announced the addition of a new gas nitriding system at its corporate headquarters located in Waterloo, Iowa. The system increases their Iowa location’s size capabilities for gas nitriding and gas nitrocarburizing. The equipment can also be used for stress relieving.
The new gas nitride system can accommodate parts up to 26′ high and has a trademarked heat treat process for wear and corrosion, UltraOx®. The equipment will serve applications within the industries of plastics, oil and gas, hydraulics and more.
“Now we are able to better accommodate large and long parts at all of our nitriding locations,” commented Mikel Woods, president at AHT.
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Heat Treat Today is partnering with two international publications: heat processing, a Vulkan-Verlag GmbH publication that serves mostly the European and Asian heat treat markets, and Furnaces International, a Quartz Business Media publication that primarily serves the English-speaking globe. Through these partnerships, we are sharing the latest news, tech tips, and cutting-edge articles that will serve our audience — manufacturers with in-house heat treat.
Take a look at new tech and equipment, an old furnace, positive profits and reports, and lasting partnerships.
International Heat Treat and Metallurgy Company Sees Doubling Profits
SECO/WARWICK’s positive figures for 2022
Source: SECO/WARWICK
“The great results of the Group were influenced by several factors. The growth of production activities in China and dynamic market development in America. Furthermore, the huge number of orders [are] related to the electromobility industry expansion. In the first three quarters of 2022, the company had over 100% more profit than in the previous year. Sales revenues amounted to PLN 448.87 million in this period (PLN 335.09 million in 2021). . . For SECO/WARWICK, 2023 will be the year of American companies.”
System aids in the production of various steel grades
Source: Tenova
“Tenova, supplier of sustainable solutions for the metals industry, has recently completed the start-up of the new 70t EAF at the Valbruna ASW Inc. plant, located in Ontario, Canada. Valbruna ASW is a specialty steel producer that produces steel and stainless-steel, based in Ontario. Tenova’s latest generation EAF unit has replaced an older EAF vessel. The spout shape of the new furnace will provide an increase in melt shop productivity, says Tenova, as well as an improvement to the
production reliability of manufacturing specific high-quality steel and stainless-steel grades.”
German blast furnace is 50
Source: Furnaces International
“A blast furnace in operation at thyssenkrupp Steel’s Schwelgern steel mill in Germany, turned 50 years old on 6 February. Known officially as Schwelgern 1 – the Black Giant – the blast furnace is 110 meters in height and has a daily capacity of 10kt of pig iron; it is regarded as one of the biggest blast furnaces in the western world.”
Hydrogen-based Steel Production Project, SALCOS, Receives Gov’t Funding
German steelmaker awarded government funds
Source: Salzgitter
“Salzgitter, Germany’s second-largest steelmaker, has been awarded almost €1billion in government funding for its hydrogen-based steel production project, SALCOS . . . The project will produce around 1.9Mt of raw steel and cut more than 2.5Mt of carbon emissions a year, according to Germany’s economy ministry.”
Foundry Group BIRN Released Its First Sustainability Report
Sustainability Report for BIRN Group
Source: BIRN
“As one of the first in its industry, the foundry group BIRN Group has just released its first sustainability report. The report is an initial step towards a more sustainable business model.”
New Pyrometer for Foundry and Liquid Metal Applications
SPOT MM smart application pyrometer
Source: AMETEK Land
“Liquid steel and metal foundry and tapping operators can now benefit from improved and smart temperature measurements for process control and product quality improvements with the new smart SPOT Meltmaster (MM) application pyrometer from AMETEK Land. The SPOT MM offers a single-sensor solution for liquid metal temperature measurements in foundry and tapping applications. This smart application pyrometer accurately measures tapping stream and liquid steel and metal temperatures independent of surface and condition changes during the process.”
Specialty Steel Provider Joins Steel Manufacturers Association
Mike Williams, President/CEO
TimkenSteel
Source: TimkenSteel
“TimkenSteel has joined the Steel Manufacturers Association (SMA) – the largest steel industry trade association in the United States and is the primary trade association representing North American EAF steel producers. Timken’s president and chief executive offi cer, Mike Williams, has joined the SMA’s board of directors.”
Nucor Steel Berkeley has ordered a new plant for its steelworks from Primetals Technologies
Source: Nucor Steel Berkeley
“Primetals Technologies has received an order from Nucor Steel Berkeley, a division of US steelmaker Nucor Corporation, for a new hot-dip galvanising (FVZ) line for the automotive industry. The line will be installed at Nucor’s plant in Huger, South Carolina. Nucor Corporation is the largest steel producer in North America and the largest recycler of materials in the Americas.”
Investing in the production of high-performance electrical steel in Shanghai.
Source: Baowa
“Fives, a leading engineering group with broad expertise in steel processing and technology, has designed and delivered thermal sections for a new annealing and pickling line (APL) and two new annealing and coating lines (ACL). The lines, designed to produce high quality non-grain oriented (NGO) grades for electric vehicle motors, delivered their first coil between December 2022 and February 2023.”
Successful Trials Will Help Manufacturer Reduce Carbon Footprint
Addressing the issue of plastic waste management.
Source: worldsteel
“Integrated steel manufacturer JSW Steel has accomplished a ‘significant breakthrough in environmental sustainability’ by successfully injecting waste plastic into Blast Furnace 3 at its Vijayanagar steel plant following extensive trials.”
Left to right: Huang Ligang, general manager, Kilnpartner; Zhang Yuejin, Chairman of the board, Kilnpartner; Michael Reisner, CEO, Aichelin Ges.m.b.H.; Christian Grosspointner, CEO, Aichelin Holding; and Fan Xiaochun, CEO, Kilnpartner, after signing the contract.
Source: Aichelin
“The thermal processes used to treat the essential components of Li-ion batteries represent a key technology in this process. These include the cathode as LFP (lithium iron phosphate) or NMC (nickel manganese cobalt) and the active anode material. Only through a highly accurate heat treatment can the crystal structure and morphology of the material be trimmed to “peak performance.” In order to achieve this goal, each manufacturer has its own processes. The common basic requirement is flexible and reliable plant technology, the so-called “kilns.”
