Maintaining precise temperature uniformity is a cornerstone of pyrometry compliance and part quality in heat treating. Yet, traditional manual tuning of multi-burner furnaces is slow, labor-intensive, and prone to inefficiencies due to nonlinear system responses.
In this Technical Tuesday installment, Ben Witoff, manager of Information Systems and Data Strategy for Fives North American Combustion, Inc, outlines a new linearization-based approach to combustion tuning. This approach offers a data-driven method to shorten uniformity adjustments, improve survey outcomes, and elevate furnace performance to higher AMS2750H classes with greater repeatability and less operator intervention.
This informative piece was first released inHeat Treat Today’sOctober 2025 Ferrous & NonFerrous Heat Treatments and Mill Processing print edition.
The Manual Uniformity Tuning Model
Heat treat furnaces require precise combustion system tuning to produce high-end parts for aerospace, automotive, and construction industries. Temperature uniformity surveys (TUS) are the accepted industry standard for verifying the quality of these metal processing furnaces. Current standards such as AMS2750H specify a temperature uniformity that must be maintained inside the furnace work zone. End users, like Boeing, GE, and Pratt & Whitney, have mandated these temperature uniformity quality standards for their suppliers who heat treat components for their products.
Today’s furnace and combustion system TUS tuning methods are slow, inefficient, and outdated. These methods require skilled technicians to make precise, manual adjustments to single components in an iterative fashion. Adjustments require this recursive approach because the system of equations governing an industrial furnace’s heat distribution is nonlinear — an adjustment in one part of the furnace system will require tweaking the set up in other area(s).
In the typical case of a multi-burner furnace which has more than one temperature measurement point, the temperature distribution across a measurement array is not directly proportional to the change in a single burner’s firing rate. Due to the system’s nonlinearity, each independent tuning adjustment has incidental, cascading downstream effects on the rest of the system. Every attempt to resolve temperature disparity in one area of the furnace can consequently bring another area out of compliance.
Reinvention of the Tuning Process
Fives North American Combustion, Inc. (FivesNA) has developed a solution that shortens the time of the temperature uniformity tuning process when used before each TUS and optimizes the furnace temperature uniformity. The North American CertiFire panel implements a patented (Robertson and Dzik 2024) temperature mapping algorithm that creates a linear approximation of any furnace’s system of equations, regardless of its geometry or complexity. Once linearized, the temperature distribution can be resolved through simultaneous adjustments.
The temperature mapping algorithm creates a response matrix that correlates changes to the furnace’s heat inputs with changes in the steady-state distribution of heat throughout the furnace’s work zone. A thermocouple array is used to measure the work zone’s three-dimensional temperature distribution while the furnace’s burners are modulated. It is critical to the accuracy of this response matrix that the burner modulations are precise and repeatable. To accomplish this, actuated gas valves are inserted in the gas line to individual burners taking the place of a manually adjusted limiting orifice valve.
Each individual burner modulation has its own characteristic effect on the entire work zone’s temperature distribution. Figure 1 shows two different burner modulations and Figure 2 shows the resulting furnace temperature distribution over the same period. Nine thermocouples were placed on a rack within a furnace in accordance with the AMS2750H standard for this furnace volume and class, with eight thermocouples at each of the cubic work zone’s vertices and one in its center (SAE International 2022, p 44, Table 17).
Figure 1. Two different burner modulations (Source: FivesNA)Figure 2. Temperature response to two different burner modulations (Source: FivesNA)
The firing rate of each burner was increased to a fixed amount for a set number of minutes. The second burner was not adjusted until the work zone’s bulk temperature returned to the baseline average temperature. The two burners noted in Figure 1 were firing in the same plane, several feet from one another. Despite the burners’ close proximity and similar adjustments, their effects on the temperature distribution shown in Figure 2 are uniquely different. Not only does the overall rate of temperature change differ between the curves, but so do the individual thermocouple reactions. Thermocouple 5 (shown in orange), for example, shows the largest change in temperature for the first burner’s modulation, but experiences a much weaker response during the second burner’s modulation.
Mathematical Approach
The linear approximation of the furnace’s system of equations can be written as shown in Figure 3. Where vector T represents the temperatures of q thermocouples, vector B represents the bleed valve modulations of r burners, and response matrix K represents their relationship. By compiling each of these burner modulations and their resulting temperature effects, the furnace’s unique response matrix can be calculated using the formula shown in Figure 3.
Figure 3. Linearized furnace equation and response matrix creation
Once the response matrix is known, the linearized furnace equation can be reversed. By dividing a vector of thermocouple temperatures T by the response matrix K, the equation yields a vector of automated burner gas valve positions B. In a steady state furnace, starting with a vector ΔT representing the required changes in temperature for each thermocouple to reach the survey temperature, this equation can solve for ΔB, the necessary burner gas valve adjustments to achieve temperature uniformity.
The process of training entails the CertiFire map out the general valve positions needed to bring the furnace close to uniformity. Metaphorically, it is writing the manual of the furnace’s behavior which takes time to develop (a few hours). The tuning operation, which is the next and final step after the training, is like reading the manual and applying the guidelines set by the training. This process takes only a few minutes to dial in the valve positions for improved uniformity, as discussed below in the case study.
Case Study: SIFCO Industries, Inc. – Cleveland, Ohio
SIFCO furnace 8001 is a single zone box furnace with four high velocity burners firing above the load on the left wall of the furnace and four high velocity burners firing through piers below the load on the right side of the furnace. All burners were configured with a cross-connected variable ratio regulator. The combustion air was fixed for fuel-only turndown, and furnace control was achieved through a single impulse air bleed valve, which affected all regulators equally.
Adding the linearizing technology to furnace 8001 required the installation of eight actuated gas valves, replacing the existing manually adjusted limiting orifice gas valves, and a PLC subpanel. This added subpanel controls each motorized actuator independently. To drive the actuators, the subpanel was wired with two inputs from the existing panel: the tuner control variable (CV) over a 4-20mA signal, and the controller set point (SP) over ModbusTCP. The existing control panel was left in-place and is still the primary furnace control interface.
Pyrometry
Furnace 8001 is certified according to the AMS2750H pyrometry standard at the following three temperature SPs: 900°F, 1500°F, and 2100°F. Additionally, the survey process requires first holding the furnace 100°F colder than each SP (800°F, 1400°F, and 2000°F) before increasing the temperature to the desired production SP to prevent overshoot.
According to the AMS2750H standard, the furnace’s internal volume requires nine type-K thermocouples placed at each vertex of the cubic work zone and one at the geometric center for temperature measurements during certification. Furnace 8001 had historically been certified as a Class-III furnace (±15°F). The client’s goal was to reduce the overall temperature span at each of the six SPs to move furnace 8001 to AMS7250 Class-II (±10°F).
Installation Overview
The solution was deployed on furnace 8001 the week of March 31, 2025. Six SPs across four calendar-days (April 4–7) were trained and tuned. The training and tuning algorithms run unattended, so the estimated labor hours to set up and run the process at all six SPs was approximately two hours.
Example Training Experience – 800°F
Training at 800°F ran from 7:52 a.m. to 10:16 a.m. on April 5, 2025, for a total of 2 hours and 24 minutes. The furnace PID tuner was disabled for this training, and each burner’s actuated gas valve was locked in place at its last position. One at a time, each automated burner gas valve was opened by 50% to allow more fuel to flow for three minutes before lowering back to its initial position for 15 minutes. An adjustment amount of 50% was arbitrarily chosen to elicit a strong temperature response.
As each burner’s firing rate was adjusted, a unique temperature characteristic was measured across all 12 thermocouples (SIFCO requires three additional thermocouples for its TUS). The difference in each thermocouple’s temperature rate of change and amplitude is the foundation for the training algorithm’s furnace map.
Example Tuning Experience – 800°F
After the 800°F training was completed, three tuning iterations spaced eight minutes apart at 10:40 a.m., 10:48 a.m., and 10:56 a.m. on April 5, 2025, were conducted. The result of the tuning iterations was a reduction in the temperature span (hottest minus coldest) from 20.2°F to 5.3°F, and a reduction from +4.7°F, -15.5°F to +1.3°F, -4.0°F with respect to the SP, well within the range of an AMS2750H Class-I furnace.
Figure 4. Thermocouple temperatures during 800°F tuning (Source: FivesNA)
The temperature range, shown in Figure 4, illustrates the initial span on the left half of the chart. A clear reduction in span can be noted at the inception of the first tuning iteration around the 10:40 a.m. mark. Note how not only are the coldest and hottest thermocouples brought in towards center, but the overall spread is also closer centered on SP. The same process was done for five additional SPs yielding the data in Table 1.
SP [°F]
Operating Time
Temperature Span [°F]
SP Variation [°F]
Effective AMS2750 Class
Training
Tuning
Initial Span
Tuned Span
Initial SPV
Tuned SPV
800
2.4h
15m
20.2
5.3
+4.7, -15.5
+1.3, -4.0
Class-I
900
–
10m
6.3
5.7
+1.9, -4.4
+1.5, -4.2
Class-I
1400
2h
1h
42.9
9.7
+22.7, -20.2
+4.6, -5.1
Class-II
1500
–
10m
11.9
11.0
+9.0, -2.9
+7.2, -3.8
Class-II
2000
2.4h
25m
21.3
11.5
+13.9, -7.4**
+3.4, -8.1**
Class-II
2100
–
8.5h*
28.6
9.0
+20.1, -8.5**
+4.8, -4.2**
Class-I
* Tuning at 2100°F was left to run overnight to test the effectiveness of longer hold times. ** Bulk furnace temperature read on average 20°F hotter at 2000°F and 2100°F than the controller SP. Reported SP variations are referenced to the median thermocouple instead of controller SP.
Note that the training was only needed for three temperatures. Since this initial data was captured, SIFCO has conducted three monthly TUS surveys. Prior to each survey, only tuning by the Certifire at the required temperatures was performed. The simplicity, efficiency, and accuracy of the linearizing technology ensures the subsequent client TUS will easily pass and maintain Class II uniformity.
Operating this linearizing technology does not violate furnaces with multiple temperature survey temperatures per AMS2750H because the valve positions are repeatable and maintain the original settings and pressures from the tuning prior to the TUS and will remain in that position until the next tuning (SAE International 2022, Section 3.5.4.1.1k).
Conclusion
Figure 5. Nick Klusty of SIFCO Forge
The adoption of linearization-based combustion tuning represents a significant step forward for the heat treat industry. SIFCO’s Facilities & Maintenance Manager Nick Klusty reflected on their new capabilities, saying, “We had been struggling to maintain Class III on this 8001 furnace for years. It took days to tune the furnace in preparation for every monthly TUS. Now it literally takes minutes. The North American CertiFire tunes so much better than we could ever achieve by hand. So good that we now have a second furnace available for Class II work, which opens up a new channel for production saving us the time and money of using outside services to heat treat Class II products.”
By replacing manual, iterative adjustments with a data-driven, repeatable process, furnace operators can achieve tighter temperature uniformity in less time, reduce the risk of failed surveys, and expand furnace capabilities to higher AMS2750H classifications. Beyond compliance, this approach enhances process stability and operational efficiency, ensuring that heat treaters are better equipped to meet the increasingly stringent demands of aerospace, automotive, and other critical industries.
References
Robertson, T., B. Witoff, and J. Dzik. 2024. Method and Apparatus for Improving Furnace Temperature Uniformity. U.S. Patent 12,104,788, filed October 1, 2024.
Ben Witoff Manager, Information Systems and Data Strategy Fives North American Combustion Inc.
Ben Witoff is the manager of Information Systems and Data Strategy at Fives North American Combustion Inc. After founding the company’s data engineering department in 2019, his work focuses on the development of IIoT-enabled combustion technologies and integrating data connectivity and advanced analytics into industrial processes. A Class of 2023 Heat TreatToday 40 Under 40honoree, Ben has also been a guest on Heat TreatRadio Episode #77: Algorithmic Combustion Tuning with Justin Dzik and Ben Witoff at Fives.
For more information: Contact Ben Witoff at ben.witoff@fivesgroup.com.
This presentation was featured in a Heat Treat Radio episode with Justin Dzik, manager of business development, and Ben Witoff, manager of data engineering, at Fives North American Combustion, Inc. In the episode, Heat Treat Radio #77: Algorithmic Combustion Tuning With Justin Dzik and Ben Witoff at Fives, Heat Treat Today publisher Doug Glenn learns about a never-before-seen combustion system tuning technology from Justin and Ben. Hear from the experts themselves how this system will save time, money, and personnel and can be adapted to virtually any furnace system.
An excerpt from the episode: "Where we’ve focused on is direct-fired heat treat furnaces and torch furnaces, and we’re looking to branch out into other things. We’ve even had discussions internally of using this on resistive heaters for electric heaters because we know 'the green wave' is coming. The product itself has been stated pretty well. The algorithm has no idea that it’s even a furnace. It could be applied to pretty much everything."
In thisHeat TreatRadioepisode, host andHeat TreatTodaypublisher Doug Glenn learns about a never-before-seen combustion system tuning technology from Justin Dzik, manager of business development, and Ben Witoff, manager of data engineering, at Fives North American Combustion, Inc. Hear from the experts themselves how this system will save time, money, and personnel and can be adapted to virtually any furnace system.
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): This is kind of a new technology that I haven’t seen before in the market. We’re going to be talking about combustion system tuning. We have here with us today Justin Dzik from North American Combustion and also Ben Witoff. Justin is the manager of business development there in Cleveland and Ben is the manager of data engineering. We’re going to hit on, I think, what is a pretty interesting new product that you guys are developing. When I first saw and heard about it, I thought, “ I have not heard of anything like this before.” I think our listeners and viewers will find it of interest.
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The name of the product is called CertiFire™. Before we get too far into it, Justin, if you don’t mind, can you give us just a brief background about you? And why don’t we have you, if you don’t mind, just give us a thirty second blurb on Fives North American Combustion, as well, please.
Justin Dzik (JD): As Doug already said, I’m the manager of business development and I’ve worked at Fives for 15 years now in various different roles, primarily focused on the forging and heat treat markets doing uniformity tests, and that’s really why this product is so close to us.
Fives North American is a company that has been around for about one hundred years; it’s located in Cleveland, Ohio. We produce combustion equipment, but we also do turnkey systems, we do furnaces, direct-fired furnaces for the forge heat treat but we also supply combustion equipment for pretty much every industry that needs heat, which is quite a bit.
DG: I would like to mention also for those of you who are old-timers, somewhat like me, Fives North American Combustion should be recognizable. The old company name was just North American Manufacturing. They are in the Taj Mahal on Grant Street just south of downtown Cleveland.
Ben, how about you? If you don’t mind, give us a quick blurb about yourself and your role there.
Ben Witoff (BW): I’ve been here just about 10 years; my 10-year anniversary is going to be next year. I’ve worked in various R&D roles since I’ve been here. I started as a burner designer, worked with FEA CFD modeling, moved into thermal processing engineering, and then, just a few years ago, I started the data engineering department here so that we could try to augment our combustion and industrial equipment with sensors, with IoT, with data, with smart engineering, and just to try to take a step further.
DG: Industry 4.0, IoT and all of that stuff is very, very interesting. That’s what caught my attention on this thing.
Justin, without going into any great detail, if someone only watched the first two minutes of this podcast, from a 30,000-foot view, what is CertiFire™, and why should people care about it?
JD: The CertiFire™ is, as you already stated, an automated tuning device for temperature uniformity certifications. I think pretty much everybody that’s going to watch this podcast is probably going to know that they can be extremely time consuming to do, they take a lot of time and a lot of intelligence to actually tune the process. This device takes all of that and does it all itself. It does all the automated burner tuning, all the valve adjustments, it locks it all in and tunes it for whatever class uniformity you need.
DG: I did want to hit on that, too, because we’re talking about trying to tune the combustion system on a furnace so that that furnace is running, first off, optimally (not wasting energy), but also, we’re talking about trying to make that system uniform, trying to make the work zone uniform, inside that furnace. So, again, most people will already now this, but it’s always good to hit on some basics here, because there may be people listening that don’t know some of the basics: why is this work zone uniformity, the area inside the furnace, why is it important that it be uniform? And then, if you can, maybe hit on what we mean when we say, “furnace classifications.”
JD: Obviously, it’s important because the parts that are going into these furnaces can be used for a variety of applications, like everybody knows, aerospace being a primary part class that’s going in. Because of that, and the metallurgy required, everything needs to be within a certain temperature band in order to get the same metallurgical properties, after they forge it, or heat treat it or whatever. So, it’s extremely important to make that work zone as tight as possible and as consistent as possible, and as we can all imagine, having a work zone about 3 or 4 feet away from essentially a live fire coming out of a burner, is extremely difficult.
As you said already, there are classifications, there are different codes that govern the work zone classifications like AMS2750 Revision F is the most recent one, Rolls Royce has their own, and pretty much all of the aerospace suppliers have theirs. So, the classifications really govern how tight the uniformity band has to be in that work zone.
There is class 1 which is basically ±5 degrees Fahrenheit anywhere in that work zone and it goes all the way up to class 6 which is ±50 degrees, so much more lenient. Obviously, class 1 is the hardest, probably all heat treat stuff; class 6 is probably some heavy forgings.
DG: As we move up the furnace classifications, as we move up from going ±5 to ±50, the lower classifications are where it’s really critical that any type of heating source, whether it be electric heating elements or combustion, be well tuned because you want the whole entire work zone to be uniform.
But we’re talking specifically about combustion tuning. Justin, I’ll address this with you and then Ben- I’m coming to you with the next question: How have combustion systems typically been tuned in the past — in fact, I would say probably 99% of them are still tuned even now — and what are some of the major issues that we run into in the way we’re currently doing it?
JD: Obviously, there is a variety of complexity of systems out there. There are furnaces still in operation that we put in in 1960. The number of valves they have on there, they’re probably more manual valves so there’s a lot of manual tweaking of things going on right at the burner. The more advanced systems out today have automated valves, but you’re still doing manual adjustments in a PLC, probably, that you’re trying to tweak. Everybody knows, and I think Ben really likes to use this statement: it’s a game of whack-a-mole. You adjust a burner here and it goes out of compliance over here and so you run over there. I’ve been on hundreds of surveys where I’m running around the furnace trying to watch my temperature map that I have in my hand. It can get very tedious, and it takes a lot of know-how and a lot of experience, I believe, to tune these furnaces.
DG: So, there is, I believe to a certain extent, an art to it now, very much dependent, I’m guessing, on your specific furnace, your specific burner, your specific burner configuration, and what mode of combustion you’re using, whether it’s pulse fire or whatever, right? All of those things are “the art of combustion.” It kind of takes us back to that black art that heat treaters are trying to avoid, where you’ve got to figure it out, each one individually. CertiFire™ is basically going to help us eliminate that.
Ben, if you don’t mind, how does CertiFire™ work, why is it better, and what kind of results do you think we can get in the sense of amount of time spent trying to tune a system and uniformity?
BW: As Justin mentioned, I love using that term “whack-a-mole.” I think it’s a great way to describe it, it’s a great way for people to understand. You bop down one of those thermocouples, you get it into the right temperature, and then the next one popped right back out. And the reason that happens is because these furnaces are nonlinear systems.
When you look at the inputs and you look at the outputs and you try to model it just from a purely physics or mathematical perspective, it’s not something that can be tuned linearly, you can’t just adjust a valve and then adjust the second valve and expect all of the adjustments from the first one to carry over. You’re constantly throwing one thing out of whack when you bring another thing in.
You also touched on this with your other question: there are so many other factors that affect the uniformity of the furnace. If we built five identical furnaces in our factory and got all of the burners set up identical and we shipped then out to five different locations, they’d all be different — completely different — because it’s the humidity on that day, it’s the temperature, it’s the elevation that it’s installed, it’s whether or not the facility is indoors or if they have their garage doors up- there are so many different factors that affect it. It’s the humidity when we mix the refractory on that day that affects it.
So, you can’t just tune it, forget about it, and ship it off. It needs to be done on site. And today, it’s kind of that “art” — it’s someone that is highly trained, they have years of experience to do it. They’re the “furnace whisperer,” they can figure out exactly how they get those systems into tune.
So, what we did is we took a step back and we said- how can we try to approach this mathematically? The first thing that we identified is we cannot be adjusting one at a time. You don’t adjust burner one and then look at the temperature readout and then adjust burner two. We can’t do it that way. So, we said we have to figure out how we can model that 3D space, those inputs and those outputs and that relationship between them, and that’s the fundamental nature of what the CertiFire™ does.
Photo Credit: Fives North American Combustion, Inc
We use this phrase “response matrix” and this is the way that we’ve created this virtual map of the furnace. It maps all the inputs — those burners, those heat sources — to all the outputs — those thermocouples in the work zone, that temperature measurement point.
And what we do is we go through this training phase for every furnace where we modulate our burners, we change the firing rate in a known way for all of the burners and then we measure exactly how those temperatures of those thermocouples in the work zone change. And the way that they change, the speed at which they react, the amount of time it takes to heat up and cool down, and the exact 3-D map of where those thermocouples are and how they react to each burner and where those burners are, is what this response matrix is.
The beautiful thing about the math behind it is you can solve the equation forwards or backwards. So, it’s easy to modulate a burner; it’s an independent variable. You can tell exactly where to be. You don’t know where the temperature is going to be, but you can measure it once you modulate that burner. So, that’s our equation.
We build the forward equation, and the beauty of CertiFire™ is we just flip it backwards. We solve it the other way. We say, “Where are all our thermocouples today? What’s our survey temperature?” All right, well, this one is 5 degrees hot, this one is 20 degrees cold, so you have all of your ΔT’s and then you say- well this if is my array of delta T’s, then divide by their response matrix. What’s my array of delta burner adjustments?
So, it solves for all the burners simultaneously, it takes all the adjustments into account, it gets rid of that whole whack-a-mole game, and it tells you burners 1 through however many you have need to be adjusted x% up, x% down, you do the adjustments, it looks at it and says, “Is it good enough?”, and if not, make another adjustment.
DG: Very interesting. So, this is all done through algorithms and things of that sort, I assume, the “secret sauce.”
BW: Right, exactly. It’s some fairly simple math but it’s this matrix math where we’re trying to model multiple inputs and multiple outputs, and we’re trying to map N-inputs to M-outputs. It’s not necessarily linear still but we’re making these linear approximations for a nonlinear system.
DG: I’m going to create a fictitious persona here and ask you about the capabilities: I’m a guy who owns a furnace that is a class 4, class 5, class 6 — let’s say it’s not super-precise as far as temperature uniformity (±15 or upwards). It’s an older system. I’ve got old burners on there, and I’ve got old valving on there. In order to use the CertiFire™, do I need to update those burners and/or valving so that it can be precisely tuned, or does the CertiFire™ work on any type of current combustion system?
BW: I guess I would say yes and no. I’ll get into the details on that because it can be kind of a confusing or irritating answer. I’ll start with yes, because the fundamental algorithm really doesn’t care that it’s a furnace at all, it doesn’t care that it’s a cube, it doesn’t care that it’s X number of burners or whatever dimension. The fundamental algorithm is simply that you map inputs to outputs, and they can be any different size, they don’t have to be the same size, and then it allows you to solve it backwards. The fundamental algorithm, the piece that is the heart of the CertiFire™ can absolutely work on that furnace.
The reason I said no is because the first piece of technology we’re trying to tackle with the CertiFire™ is a more advance PLC controlled system. The way that we do tuning today is we use actuated bleed valves per burner on our furnaces so that we can make that fine tuning automatically through a PLC adjustment. Because the PLC can control those actuated bleed valves per burner, it’s really simple for a device to just simply plug in with the data cable and then immediately take over the furnace and make these adjustments automatically at the push of a button.
That’s the first tier of furnace technology that we’re trying to tackle, that we’re trying to release a product for. What we’re working on after that tier, our lower tiers, are furnaces where customers are wanting to retrofit to a bleed valve system and then, finally, after that, are customers who are unwilling or don’t want to upgrade to that retrofit system.
Because no matter how you make that adjustment, the easiest way is a bleed valve if you already have it. But no matter how you make it, if it’s eliminating orifice valve and it’s a technician with a screwdriver in his hand, it’s the same algorithm. The only difference would be the CertiFire™ HMI may print out a sheet of paper that the guy can walk around the furnace with or he’s carrying an iPad and it says “Burner 1, quarter turn right, burner 2, eighth turn left.” He can make them one after the other in series because the solution itself is still a parallel solution.
DG: Obviously, it’s going to take more time and there’s more manual interaction there with that latter example you were giving.
BW: Right. But it’s certainly not more manual than they would tune it without the CertiFire™. It doesn’t take that furnace whisperer technician to get that done — anyone can use that sheet and make the adjustments that it tells them to make.
DG: It sounds like, with yours, even if you’re doing the adjustments manually, let’s say, in your latter example, you’re going to go out and you’re going to make an adjustment to all 12 burners on your furnace and come back and see how that goes. Whereas if you’re the whack-a-mole furnace whisperer, he’s going to go out, adjust one, come back, see how it goes, go back out and adjust another one. So, that makes some sense.
Photo Credit: Fives North American Combustion, Inc.
How about installation of this thing? You mentioned data cables and things of that sort. How complicated is this thing to install, and how much time to install?
BW: Starting with the first tier of customer that we’re trying to talk about here, if there is an existing furnace, if it has the panel that we built for this customer, if they have these bleed valves with actuators on them talking to the PLC today. If we were to walk into that facility, we would have a box that is literally plug-and-play. It needs power, it needs data, and then your HMI has a green “go” button on it. It’s something that we would preconfigure because we’d understand the tags inside of the PLC and how to communicate to all of the valves. It would actually be that simple.
If it was built by somebody else or it was an older panel or we didn’t know how the PLC worked, it would probably take some time for us to understand it from the controls perspective so that we could get all of the tags coded properly, but that’s not anytime where the customer is not running. They’re still running, we’re just in the background reading some PLC information.
And then, finally, if this is a customer that wants to add that equipment, if they’re looking to upgrade if their equipment is older, or maybe their class 5 today but they really want to be class 3 or maybe even class 2, we would probably suggest, with or without CertiFire™, to upgrade to those bleed valves per burner. We think we can get better control with that and in that case, maybe the customer has to shut down the furnace for a week while we do the installation and then once it’s installed again, it would really be that simple as a plug-and-play device with a data cable.
DG: Justin, I’ve got a question for you, now: I can imagine that some of the viewers/listeners are wondering, “Yes, I’ve got a combustion furnace I’d like to do this. Does it make sense for my furnace?” Are there any systems out there that you can think of, any furnaces with combustion, where the CertiFire™ would not make sense? Are there any applications or anything along that line?
JD: Honestly, I think that if you need to comply or certify your furnace to any uniformity standard, The CertiFire™ could definitely help. As Ben stated, there are different tiers of the product and how it would actually be from the customer experience. From a totally automated state to one where CertiFire™ is like the assistant to the person performing the tuning. But there are no configurations — step fire, pulse fire, excess air modulated, everything under the sun — the CertiFire™ can help solve those problems for them.
DG: So, I assume the aluminum industry, steel industry, heat treat industry, generally speaking, have no problem firing into radiant tubes?
JD: So, obviously, we’re at the beginning of the launch of this product, so where we’ve focused on is direct-fired heat treat furnaces and torch furnaces, and we’re looking to branch out into other things. We’ve even had discussions internally of using this on resistive heaters for electric heaters because we know “the green wave” is coming. The product itself has been, I think, stated pretty well.
The algorithm has no idea that it’s even a furnace. It could be applied to pretty much everything. I think this is going to be one of those products where we made it for this — we do this all the time with our burners — and then we find all these other ancillary uses for it because it’s such a revolutionary kind of idea.
DG: As you were talking there, I was thinking to myself, “Yes, you know, if you designed it so far for direct-fired, to a certain extent, radiant tube applications might add a little more complexity to it because you’ve got heat transfer rates through a tube, but, I suppose, still, it’s going to do the job because it doesn’t know.
JD: Yes. There is a thermocouple having a response and then there is this burner input. The way the heat transfer happens is going to change, but you’re going to have to modulate the radiant tube to get where you’re going to need to go.
Photo Credit: Fives North American Combustion, Inc.
DG: So, it’s “heat source agnostic,” we’ll call it.
Does this system have any type of reporting? I guess you did say, Ben, that after you do the first test and establish the response matrix, there is some sort of a report, I assume, when you want to tune it, but what is the reporting, what’s it look like? What are people going to get from this thing? And I guess I want to ask about the platform that it’s on, I guess it’s just PLC-based, right?
BW: The tuning is done through the PLC because it’s communicating with those actuated bleed belts. The actual box itself is essentially a computer, so it’s running our own custom code and it’s executing that to communicate with the PLC. We’ve tried very hard to make it PLC agnostic so it can communicate with the most common things we see in the market today. It can communicate over common protocols like Modbus, it can communicate with Rockwell’s EtherNet/IP or Viessmann F7. So, that is essentially just a computer — it’s a Linux box that can talk all of those languages at once, so it can just plug-and-play with the PLC.
The reporting we’ve tried to make look similar to what people are used to. People are used to looking at chart recorders to see temperature, so we have essentially a more advanced display of live data, chart recording for temperatures for valves that you can see exactly where it is with historical data easily available at a click and drag so you can see where it was and where it is today.
As far as an output of the report, we’ve also tried to make that look, as much as possible, like what people are used to seeing. With the AMS certification, there are guidelines about what data needs to be stored, what needs to be reported, and while we’re not doing the certification, that type of time-stamped temperature by furnace ID, by who ran the test — all of that information is generated in these reports every time that you do this response matrix as training creation, and then every time that you solve that and do this tuning of the combustion system.
DG: I can see some people wondering about this: Is it Cloud-based at all or is it all on site?
BW: It’s entirely on site. There is certainly the option. I know some customers (although it’s rare but it is growing today) want their information to be more accessible than it is today. But if a customer doesn’t want that, if they want everything restricted to plant, if they want it restricted off of the plant network and even adjust on the box itself. We can do that as well. Today, we don’t have Cloud connectivity built into the base box. We wanted to make it simple, we wanted to make it easy for customer compliance. It’s an option, it’s something we can do, but it’s not something we wanted to pursue in the first release.
DG: You’re avoiding a lot of potential internet cybersecurity issues with that.
I have a forward-looking question for you. By the way, I should mention, I’m sure by the time people listen to this, the AISTech Show will be over because it’s scheduled for next week (we’re recording this on the 10th of May and it’s scheduled for the 17–19th). I know that you guys are giving a presentation there so perhaps we can reference that on this podcast and give a link for it. . . CLICK HERE.
I know you’re just launching it. Actually, when did you launch it? Has it been weeks, months, or a year?
JD: I think it’s been about a month.
DG: So, it’s relatively new. As I say, we’re doing this on May 10th, so let’s say, April or late March you launched this thing. Have you put any thought into the future? Do you have dreams and hopes, and, if so, what might they be?
JD: Absolutely, we have some plans. Some immediate plans are we’ve talked about the tiers and how we’re going to keep pushing forward with making this a product that is for all furnaces for all direct-fired furnaces, to start, with manual valves and automated valves, so we’ll get to the tier 1, 2, 3.
Then, a big trend we’re hearing as we’re talking to customers is more gear towards predictive maintenance. Obviously, we need to tune the furnace, but the customers don’t want you tuning the furnace every time they need to certify because that calls into question their parts from the last quarter or half year that they’ve been doing.
So really you tune once and then you probably go a year; hopefully on our furnaces we go many, many years without drifting. But the box can also be used for some predictive maintenance. Use the thermocouple inputs that we have to measure the box shell temperature, see if the fiber is degrading, see if you’re up for a realign, see if your flows need to be readjusted. So, there’s a more predictive nature to the retuning process rather than a reactive nature. That’s really going to be the next step.
Then we’ll look forward to see if there’s other type of heating — like you said, radiant tubes or resistive heating. I think that’s a little bit further in the future, mostly because we’re, obviously, a gas combustion company so we’re focusing on what we know first and then we’ll build out from there.
DG: So, you’re saying some of that stuff that you’re hoping for the future is not really even combustion related, you’re going to be doing condition of the furnace.
JD: Right, like a furnace health monitor. I think everybody wants to know they’re running that furnace pretty hard (especially in a forge environment, you’re beating the hearth pretty good). To have a one-month out warning, “Hey, you might need to shut down, rather than a catastrophic failure.” We’ve gone into furnaces too much where there’s been a hole in the roof, because the fiber fell out or they just didn’t know about it. We’re trying to help customers out before something like that happens.
DG: Right now, I know almost all of the burners (the stuff you’re currently doing) are all hardwired, correct? Is there any thought about making them wireless? Is that even a reasonable thing to think about or not?
JD: From the burner standpoint or from the CertiFire™ standpoint?
DG: From the CertiFire™, in the sense of controlling and getting the data in and out. Maybe it’s a silly question, but I was just wondering. Right now, you’re just hardwiring all this stuff.
JD: That’s correct. Generally, that’s currently the way furnaces are configured. They’re all hardwired to a local PLC. Ben could probably speak a little bit more about it. I think we’ve talked about ways to wirelessly link devices more as diagnostic devices, not controlling wirelessly. You can’t really control them wirelessly because of the response time, but diagnostic components could be wireless.
BW: One of the first things that we did when the CertiFire™ was in prerelease was we were designing this box to essentially plug and be installed on that furnace. Then we took a step back and we tried to consider who’s going to be using this, how do they want to use it, what do their facilities look like?
A lot of people have multiple furnaces — maybe as little as two but sometimes upwards of twenty furnaces. Maybe you don’t want to install it permanently, maybe you want to be able to move it around, or maybe if you have a plantwide network and intranet there, you can plug this in your control tower and you can sit in an airconditioned room with one CertiFire™ and talk to every furnace at once.
That’s something that we put into that release from a month ago so the release CertiFire™ can communicate with all of your plant network at once (if you have the plant network), or just with that one furnace if you want to plug it into that one isolated furnace. We should be able to essentially it fields wirelessly you can communicate to whatever is on the network at once.
JD: Like you said already, we’ll be AISTech next week, (it will probably lapse this podcast). Then, I’ll also be presenting at the IFC (International ForgeMasters Congress) in June and with future engagements at Furnaces North America. This is our roadshow this year.
DG: You’ve got a lot to talk about! Like I said, I don’t know about you, and I know the answer to this question but I’m going to ask it anyhow.
BW: Nothing that I’ve seen.
DG: I don’t think anybody else has anything like this, as best I know. If they did, they’d be foolish to say so. But I haven’t seen it. I don’t know. Maybe they are and I’m going to catch grief for saying that.
It’s an interesting new product and I wish you guys well. I hope you’re very successful.
Good to have you with us, guys. Thanks very much for joining us.
This presentation was featured in a Heat Treat Radio episode with Justin Dzik, manager of business development, and Ben Witoff, manager of data engineering, at Fives North American Combustion, Inc. In the episode, Heat Treat Radio #77: Algorithmic Combustion Tuning With Justin Dzik and Ben Witoff at Fives, Heat Treat Today publisher Doug Glenn learns about a never-before-seen combustion system tuning technology from Justin and Ben. Hear from the experts themselves how this system will save time, money, and personnel and can be adapted to virtually any furnace system.
An excerpt from the episode:
"Where we’ve focused on is direct-fired heat treat furnaces and torch furnaces, and we’re looking to branch out into other things. We’ve even had discussions internally of using this on resistive heaters for electric heaters because we know 'the green wave' is coming. The product itself has been stated pretty well. The algorithm has no idea that it’s even a furnace. It could be applied to pretty much everything."
