Weld seam tracking: The ultimate guide for 2025 - Standard Bots

Jul. 28, 2025

Weld seam tracking: The ultimate guide for - Standard Bots

Welding without weld seam tracking is like trying to draw a straight line while riding in a car over potholes — it’s not going to end well.

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In high-speed manufacturing or custom fabrication, seam tracking keeps welds consistent, airtight, and structurally solid.

Traditional setups use those expensive sensors and rigid programming, but cobots? They’re out here tracking seams in real time, adapting on the fly, and making welding automation smarter and way, way smoother. (Which is why we’ll also throw in an awesome cobot at the end.)

In this article, we’ll cover:

What is weld seam tracking?
Traditional seam tracking vs. cobots for seam tracking
Technologies used in weld seam tracking
Benefits and challenges
Best use cases
How to choose a good tracking solution
Trends of weld seam tracking with cobots

What is Weld Seam Tracking?

Ever tried to draw a straight line on a shaky bus? That’s what welding without weld seam tracking is like — except instead of a wobbly doodle, you’re left with bad welds, wasted materials, and a boss who suddenly questions why they hired you

Weld seam tracking fixes that by making sure robotic welders stay locked onto the seam, even if the material shifts or the setup isn’t perfect.

Here’s how robots keep their welding game tight:

Laser-based tracking: This system shoots a laser at the seam to map it out before the welding even starts. Think of it as giving the robot night vision goggles so it never loses track of the weld path.
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Vision-based tracking: Cameras and AI work together to watch the seam in real time, adjusting on the fly to prevent welds from looking like your first attempt at using guyliner.
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Tactile tracking: A probe physically follows the seam, guiding the robot based on feel. This is especially useful when the weld is buried under dust, grime, or whatever factory nightmare is making visibility impossible.
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Arc sensing: This method tracks changes in electrical resistance within the welding arc itself, letting the system detect where the seam is without any fancy cameras or lasers. Perfect for when high-tech gear isn’t an option.

Traditional seam tracking vs. cobots for seam tracking

Old-school weld seam still works, but it's clunky, expensive, and makes you wonder why you're still dealing with it. But cobots are more user-friendly, faster, and make fewer mistakes — they’re a major upgrade.

Here’s how traditional systems and cobots stack up:

Here’s why cobots are winning:

Less “oops” factor: Cobots use AI and real-time tracking to self-correct, so you don’t have to babysit every single weld.
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Adapts like a baws: Unlike traditional systems that need a new program every time you switch a weld type, cobots can learn and adjust as they go along.
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Less training, more doing: Don’t need to base your life on your robot wrangling know-how — cobots are made to be user-friendly.

What technologies are used in seam tracking for welding cobots?

Cobots have got a whole arsenal of high-tech tools making sure every weld is clean, consistent, and on point. Instead of relying on human guesswork (or hoping for the best), these bots use AI, sensors, and lasers to follow seams like a bloodhound tracking a scent.

Here’s how cobots pull off precision seam tracking:

Robo-vision and AI-driven tracking: Cobots use cameras and AI to detect seam locations in real time, adjusting on the fly. A built-in GPS that actually works, yes.
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Force and torque sensors: These sensors help cobots detect slight shifts in the workpiece, so they don’t just blindly weld where they “think” the seam should be. More awareness, fewer mistakes.
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Laser seam tracking: High-powered laser beams map out weld seams with pinpoint accuracy. Basically, it’s Iron Man-level tech means every weld is in the right place.
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Hyper-techie software integration: Platforms like RoboDK and Standard Bots’s AI-powered welding solutions make it easier to sync cobots with existing welding setups. They scan data in real time, adjusting heat, speed, and positioning to keep quality top-tier.

Why this tech matters:

More accuracy, less scrap: AI and vision-based tracking mean no misaligned welds or wasted material.
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Ditch the unnecessary hand-holding: Cobots adjust automatically, so operators don’t have to constantly tweak settings.
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Easier to scale: Seam tracking tech makes cobots adaptable, so they’re not locked into one job forever.

Benefits of seam tracking cobots

Welding by hand? Cool if you like uneven seams and praying to the welding gods for consistency. But if you actually want clean, repeatable, high-quality welds without the stress, cobots are the way to go.

Here’s why cobots make weld seam tracking a no-brainer:

Nix the "oops" moments: No shaky hands, no accidental slip-ups — just perfect (or well, as close to as possible) welds.
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Scrap metal is not a personality trait: You know what’s expensive? Messing up a weld and tossing out materials. Cobots mean fewer mistakes, less wasted metal, and more money for actual useful things (like better shop coffee).
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Setup that won’t make you rage-quit: Traditional welding robots need a maze of sensors, calibration, and possibly an exorcism to get running. Cobots? Plug them in, set up the tracking system, and let them do their thing. No IT degree required.
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Plays nice with humans: Old-school industrial robots need a safety cage like they’re about to go full Terminator. Cobots work with welders, not instead of them, making your shop more efficient without turning it into a robot-only dystopia.
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Welding without lung damage: Fumes, sparks, and eye-searing light aren’t great for long-term health. Cobots handle the high-risk parts, so you can spend less time inhaling toxic air and more time doing things that don’t require a respirator.
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TIG, MIG — they do it all: Need precision TIG welds? Fast MIG work? Something even weirder? Cobots swap tools and adapt, so you’re not stuck buying a new machine every time you change processes.

Challenges and limitations of weld seam tracking cobots

Cobots are great, but they’re not magic. (Yet.) While they make weld seam tracking way easier, they still come with a few hiccups that can trip you up if you’re not prepared.

Here’s where things can get tricky:

Curvy, weirdly shaped welds? Cobots get confused: If your seams look like they were designed by Gaudi, some tracking systems might struggle. Complex weld paths need high-end sensors and AI, or your bot will start welding like it’s lost in a maze.
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AI isn’t that smart, bro: AI seam tracking keeps improving, but it’s not perfect. Sometimes, it misreads seams, especially with reflective materials or inconsistent surfaces. Just because it’s a robot doesn’t mean it’s incapable of bad decisions. (They’re getting more human every day.)
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Slower than traditional welding robots: Industrial welding robots that run pre-programmed paths are fast. Cobots, since they’re adjusting in real time, sometimes move slower to get more accuracy — which is great for precision but not always for speed.
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Not always cheap upfront: If you’re running a small shop, dropping cash on high-precision seam tracking sensors might hurt. The good news? The investment usually pays off in saved materials and better weld consistency. Think $10k to over $50k.
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Still needs a little babysitting: While cobots are way easier to use than their industrial cousins, they still need occasional human intervention — especially when working with tricky seams or different materials.

Best use cases for cobots in seam tracking

Cobots are slipping into fab shops everywhere, making life easier for businesses that don’t have time for inconsistent welds. But where do they really shine?

Here’s where cobots dominate weld seam tracking:

Short runs, high precision: If you’re making limited batches of custom parts, cobots are clutch. They adapt quickly, so you’re not wasting hours reprogramming for every tiny design change.
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Industries that switch things up a lot: Automotive, aerospace, and other industries that constantly tweak designs love cobots. They don’t freak out when you throw new specs at them.
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Hard-to-reach welds: If your seams are tucked into tight corners or awkward angles, a cobot with laser or vision-based tracking can sneak in there way better than a human or a bulky industrial robot.
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When real-time adaptability matters: Some materials shift slightly during welding (looking at you, thin aluminum). Cobots track seams as they go, adjusting in real time instead of following a rigid pre-set path.
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Shops that don’t want a full-blown robot army: Not every business needs a massive, fully automated welding setup. Cobots give smaller manufacturers a way to improve weld quality without dropping seven figures on an industrial automation overhaul.

How to choose the right seam tracking solution

You have to choose well — some systems are basically the ‘My First Welding Kit’ version, while others are high-tech geniuses. Picking the right one means balancing cost, precision, and how easy to use they are.

Here’s what to mull over before committing:

Material type and thickness: Some systems handle ultra-thin metals like a pro, while others freak out at anything thicker than a soda can. Make sure the tracker is actually built for your material.
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Welding speed requirements: If your production line moves at the speed of light, a sluggish seam tracker is gonna slow you down. Check if the system can keep up with your operations.
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Budget constraints: The good news? You don’t need to drop Tesla money on a seam tracking system. The bad news? Cheap solutions often mean cheap results. Find a solid balance.
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Software compatibility: If your existing setup and the new seam tracker speak different programming languages, you’re in for a tech nightmare. Look for systems that integrate smoothly with what you’ve got on hand.

Integrating cobot-based seam tracking efficiently:

Start small — test on a single workstation before rolling it out everywhere.
Train your team, or they’ll treat the new system like it’s a UFO.
Use AI trackers that improve over time instead of yesterday’s tech.

Trends of weld seam tracking with cobots

Seam tracking is leveling up — fast. AI, sensors, and automation are making welding smarter, and manufacturers who don’t adapt will vanish into thin air like the Avengers at the end of Infinity War. (“Mr. Stark, I don’t feel so good.”)

What’s trending now:

AI and machine learning upgrades: Welding cobots are getting smarter, learning from each job to improve precision.
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Better sensors, fewer mistakes: New tracking sensors can handle tricky weld geometries, reflective surfaces, and even dirt-covered materials. Out go the excuses.
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Labor cost reduction: Fewer human errors = less wasted material + fewer reworks = saving money. Math checks out.
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Cobot adoption is skyrocketing: More industries are ditching traditional automation for flexible cobots that are easier to program and take up less space. Expect to see them in places you’d never expect — like shipbuilding, aerospace, and even artisan metalwork.

Summing up

The idea behind weld seam tracking is keeping up with an industry that’s evolving at record speed.

We’re talking AI systems, smarter sensors, and cobot-centered automation are making welding easier, faster, and more precise.

Basically, it’s time to embrace automation or become one of those “artisanal” fab shops that are basically museums. Not a good look.

Next steps with Standard Bots’ robotic solutions

If your welds look like they were drawn by a toddler with a crayon, it’s time to upgrade. Standard Bots’ RO1 makes weld seam tracking effortless — precision, efficiency, and automation all in one.

Affordable automation: Get top-tier six-axis welding automation for half the cost of competitors, or lease it for just $5/hour. No other cobot has an 18kg payload at this price range.
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Precision at every weld: RO1’s AI-powered seam tracking keeps your welds clean, consistent, and free of defects.
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Smart and adaptable: No complicated setup — RO1 learns as it works, improving accuracy over time. It’s super easy to set up with its no-code framework.
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Safety-first design: No sparks flying in the wrong direction. Built-in sensors keep things safe for human workers.

How Seam Tracking Solutions Compare - ABIBLOG

Looking at Seam Tracking means looking at a variety of possible solutions. Depending on your process, material, and cycle time needs, the right solution will usually present itself over time.

But with if you aren't aware of ALL the solutions available?

Or just know about a couple?

What are the upsides and downsides of all the different seam tracking solutions available?

And are certain seam tracking solutions just not right for me based on what I'm welding?

Sensor technology presents a lot of possibilities to your welding operation. Some are low-cost and limited in capability and others involve large investment and thoughtful design - with huge upside is cost savings.

Laser Pointer and Manual Slides

Fixed pointers with manual slides are very basic versions of Seam Tracking. This is literally a fixed pointer of some sort. It can be a spring on a rod or a laser pointer coming down to provide a visual optic.

However configured, this option requires the operator to drive a set of slides to keep the weld on the joint. This is as cost-friendly as Seam Tracking gets for automated welding production.

Laser Pointing comes with major room for operator error. It's unavoidable. You will rely on your operator to make sure the mechanical setup is correct and the pointer is on the right spot.

Cycle time is also a major issue. Why do you invest in Seam Tracking? To save on cycle time for starters. When you rely on an operator to make decisions with slides on the fly, are you saving the time you're expecting for the investment?

If you have an operator who can manage this type of Seam Tracking with consistency and effectiveness, don't let him or her go. Otherwise, you likely can get better results and investment return going with a more advanced option.

Touch Sensing

Touch sensing in where the robot applies a small amount of voltage to either the welding nozzle or the weld wire. They both function the same way, with the only difference being the way each method translates data to the robot.

Through the voltage, the robot will come up to the work material, touch it, a short will occur, then the robot will record that position of where that recorded value is and tell the robot where the surface is.

Most occasions require at least 2 touches per joint to find the location - a vertical and horizontal surface. The robot will connect those search vectors and triangulate where the weld joint is.

On corner or outside edge joints, a third touch from the robot is typically necessary to get all the right positions to allow the robot to find and 'track' the joint.

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Touch sensing is useful as a low-cost joint tracking solution. It's a simple software-based solution you're able to apply from the teach pendant without additional systems. One of the other main benefits of touch sensing is you are able to get into tight areas because there's no additional hardware other than your robot torch nozzle impeding the joint being reached.

Touch sensing does have several limitations that make it a remedial solution for joint sensing and seam tracking. The first being that touch sensing is a slow process that adds 3 to 5 seconds per search vector. So, if you are touch sensing on a 2D part, you potentially add 6 to 10 seconds to the weld cycle, and if you are touch sensing a 3D part up to 15 seconds of time is added to the cycle time per arc start and arc end.

The number of failure points with touch sensing is also far greater than other solutions. Conditions like bent wire or dirty and scaly material make it hard to run touch sensing consistently. Touch sensing is only intended to find your arc start or arc end, and doesn't help with part variance throughout the length of the weld, so it won't compensate for inconsistent fixturing or tooling of the part.

Touch sensing is also limited by weld joint type. Fillet and lap joints are the most common and recommended joints, but even with lap joints, you have to consider material thickness. Anything less than 5 mm (1/4") can become problematic to perform touch sensing because the material thickness of the upper plate can potentially be missed by the wire - causing you to overshoot the part, or you can hit the lower plate and get a false reading.

Your robot torch also needs both a wire brake and a wire cutter outfitted in the torch package to cut the wire at a known distance away from the tip so your readings are consistent throughout the process.

Touch sensing also requires clean edges. Tack welds or poorly trimmed parts can produce false readings.

Through Arc Seam Tracking

Through the Arc Seam Tracking (TAST) is the second phase you would apply with Touch Sensing. After touch sensing, you find your arc start and arc end, then apply TAST to seam track on the Z and Y axis of the joint.

TAST is a good fit for thicker material. It also requires a weaving process. As the wire transitions from one side to the other side of the joint, the voltage is changing. This happens due to the stick-out of the wire decreasing on the change to the tip to work distance. This allows the robot to interpret the change in voltage and adjust the taught path, maintaining proper weld position in the joint.

TAST is requires 5 mm (1/4") or thicker to be stable. To do TAST at a lower thickness is not recommended. I've never witnessed TAST on material thinner than 1/4" in all my years working with seam tracking applications. Doing TAST on thin material can risk wormtracking or snaking the weld, which can reduce weld integrity.

Another reason TAST on thinner material is not recommended is the tendency of TAST to wash or remove the shoulder of the upper plate. This washing won't allow for a significant voltage change, causing the robot to search - which is where the wormtracking risk emerges.

One other limitation to TAST is you have to add cycle time because it requires the robot to weave through the joint. Typically travel speeds for TAST is limited to 35 - 50 inches per minute. TAST is likewise process limited to MIG applications only - it's not possible with TIG or Plasma.

Lastly, TAST is limited to use for mild or stainless steel. Voltages are not consistent enough with aluminum to reliably do TAST. The conditions of the material is also important. Part cleanliness, mill scale, or rust has an impact on the parameter sets because you set up the criteria of what you want for voltage change. A 2% voltage change on a negative Y due to mill scale or rust on the metal will produce inconsistent characteristics for TAST.

Dry runs are also not possible with TAST as the robot has to be welding to track. Tacks are likewise problematic because when you run over a tack, the stick-out changes, so the robot loses tracking until it comes out the other side of the tack weld.

2D Vision Systems

Think of 2D vision like a camera. It takes a reference image of an ideal part before striking an arc and matches the reference image to each new subsequent part - detecting any offsets and adjusting the weld path. It only gives a black and white image and transmits where that image is located on it's surface. 2D can't determine height or depth, and is not considered a reliable process for seam tracking.

Joints like V-joints and lap joints are very problematic for 2D Vision because it cannot determine depth on these types of weld joints. Shiny materials like aluminum are also problematic for 2D systems because they cause interference.

Usually, 2D is used for identification of parts instead of tracking. It is a vision-based system, so outside light interference is very critical to the performance of the optic. Also, the camera lens is sensitive to damage from weld spatter and arc light.

Tactile Seam Tracking

Tactile is a physical contact probe that touches the material. Tactile is typically used in hard automation and some laser brazing applications, and not a recommended seam tracking application for a 6-axis robot. Tactile rides a tip or probe inside the welding joint, and detects deviations from the edge that it touches and the original source and adjusts it's cross slides accordingly to position itself correctly over the weld seam.

Tactile Seam Tracking has a very simple operating function that can be applied to a variety of processes, including sub-arc, open arc, and brazing, which makes it a very versatile form of seam tracking. Tactile is also not limited by any kind of material, so you can tactile seam track anything from stainless steel to aluminum material without the system being affected in any way.

Maintenance is an important part of keeping tactile seam tracking system working correctly. The wearing out of parts happens often with tactile system because the tip is in constant contact with the joint surface. As your tactile probe wears and gets shorter it will have the tendency to drive your welding tool forward closer to the joint, which can produce poor welds or damage the front end of the torch entirely. It's important to check the probe for wear to make sure that it is properly standing off the torch to get the high quality weld possible.

Conditions like weld spatter and cable management are other items to inspect and maintain more often than contact-free solutions.

Tactile solutions also don't adjust to tack welds well. Tacks can lift the probe over the tack weld and lead the arc in the same direction as opposed to letting the weld torch weld through the tack as is generally recommended.

Tactile is also not adaptive. These sorts of systems follows the joint line and don't account for mismatches or gap dimensions as a result of tooling. Area calculations are also not possible. A tactile probe is going to lock into a groove and follow it with very few deviations. A great enough variance in a groove or a large enough tack weld can take the probe out of it's desired track.

Weld profiles like butt welds are difficult to perform tactile seam tracking on without a gap. Non-linear welds that force the probe to move sharply in a direction are not ideal scenario for Tactile Seam Tracking applications; it works well with large cylinder welds or pipe welding.

Travel speed is another limitation to Tactile Seam Tracking, as it typically moves at lower speeds which can slow your cycle time.

Comparing tactile to vision based seam tracking is a matter of one being a contact-based approach and the other non-contact . While it being a mechanical setup it is generally a lower up front capital investment, Tactile Seam Tracking systems in open and sub-arc applications require more maintenance as it is a mechanical process, which long term can make it a less cost-effective solution due the measuring body's sensitivity and constant wearing of components.

3D Laser Seam Tracking

Also known as Optical or Vision Seam Tracking, a 3D Laser Seam Tracking system uses laser triangulation. 3D Seam Tracking is able to be used on both hard automation and robotic systems effective with the right software package.

Conceptually, Laser Seam Tracking involves a laser beam shooting out of a device, hitting a surface, reflecting off the surface, bouncing back into the sensor, and the sensor picks up where the beams hit. So with Laser Seam Tracking, the sensor knows the distance between the laser emitter and the sensor on the camera, allowing it to triangulate the position of that material it bounced off.

In essence, you get an image of the Z (height) and Y (across) of the joint, so the sensor knows the image that it bounced off of was X (distance) dimension away from the sensor ray, and the feature that it's selecting is either positive or negative in the field of view across the Y direction.

Laser Seam Tracking does not know X direction, or how long the part is. This is why you partner the device to a control system, and the control system defines the X value - a process known as calibration. After calibration, your seam tracking system knows X, Y, and Z location throughout the weld process.

Any seam tracking solution to the weld process adds to the cycle time, but Optical Seam Tracking adds the least - typically around a quarter of a second (.25 seconds) to the weld cycle per scan.

It also moves the fastest. Optical Seam Tracking can go up to 200 inches per minute, so it doesn't limit the robot or gantry speed if high travel speeds are required. Optical Seam Tracking can also be used in processes outside of welding, such as gluing, peening, and grinding.

Laser presents a particular advantage over TAST because it does allow for the device to dry run over a part or see it offline. Material inconsistencies like rust, scale or even tacks have little or no affect over Optical Seam Tracking either, because the tracking is based solely on the imaging of the part.

Clearance with Optical Seam Tracking is a limitation. Direction of travel is another consideration to make, as the sensor has to lead the weld path at all times. This can lead to robot reach issues, torch angle issues, and the tooling and design of the part has to be well thought out.

Typically, the only material Optical Seam Tracking has difficulty with is shiny material. Reason being is anytime you emit a laser off of a material, it has to reflect. Think about the different weld joint types and how they would reflect laser beams based on the material. In a lap joint, it reflects straight back. If it's a V-joint, it not only reflects straight back but also at the opposite angles it's reflecting at - almost like a disco ball.

In these instances, sensors have a hard time then determining which beam reflecting back is the correct one. You have a lot of false beams coming back and it looks like a crosshair coming in because you're getting a lot of reflections. It's key with these types of materials that the filtering of the device and the calculation of the paths from the controller compensate for these kinds of joint/material combinations.

Material-joint combinations like aluminum diamond plate fillet welds would be impossible for Laser Seam Tracking to adequately track.

Other combinations, like stainless steel inside corners with a mirror finish, are likewise extremely difficult surfaces and joints to seam track.

While tracking these combinations with an optical system is possible, it requires an exceptional familiarity with the Laser Seam Tracking sensor to do so repeatedly.

Summary

When you're looking at Seam Tracking solutions, you are normally looking to overcome a specific problem.

Is your welding robot fast enough?

Are you having trouble with quality?

Fully automated Seam Tracking is a big investment. There's no way around it. You need to make sure your problem merits a solution this technically advanced and that the improvement gains are going to pay what a solution of this magnitude will provide.

For more Laser Vision Seam Tracking Systeminformation, please contact us. We will provide professional answers.

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