Chamfer Machine Manufacturers

Automated Chamfer machine manufacturers who make an automatic chamfer machine may succeed at efficiency, precision, or sustainability but finding an optimized solution of all three advantages remains elusive. That however is where the all-purpose MAX System Machine by James Engineering comes in. The MAX System Machine is not just another chamfering tool; it represents a shift in machining technology. Designed to deliver unmatched performance across multiple fronts, the MAX System Machine redefines what is possible in chamfering operations. Not only does it provide a repeatable precision chamfer, but its versatility extends to accommodating an unlimited array of tool heads meant for deburring, polishing, radiusing, other finishes, and more.

Changing Industrial Manufacturing

The reason James Engineering’s machines reach such a high level of optimization could be attributed to their commitment to being a full OEM manufacturer. By producing all components of the machine in-house, James Engineering holds complete control over every feature, ensuring maximum performance and reliability. This also allows for the creation of flexible machines that fit the needs of any customer. Every machine aspect can be configured to optimize any operation.   

Efficiency

Efficiency is at the core of the MAX System Machine's design. James Engineering's multi-tool machines are engineered to perform tasks quickly and simultaneously, minimizing cycle times and maximizing productivity. For example, the MAX System M5W consists of two 5-axis overhead servos with two interchangeable tools each. They perform operations simultaneously on a c-axis rotary table, making this a 4-tool 11-axis machine. James’ machines have chamfered and deburred 82 gear teeth on a part in just 30 seconds, including secondary burrs. However, companies love to talk about quick cycle times but are quiet regarding change-out time in between the cycles. James Engineering surpasses this norm of slow downtimes by achieving efficiency that extends beyond cycle speeds. By eliminating setup time and maintaining a saved log of cycles, James Engineering enables seamless transitions for running multiple parts or simply with the push of a button repeating the same part. Each machine is designed with a user-friendly control panel allowing for any operator to run them, regardless of experience. James Engineering also offers fully automated “lights out” machines that require no human operator to run parts, further streamlining operations.

Precision

Precision is another area where the MAX System Machine stands out. With consistent radiuses and cutting-edge compliant technology, James Engineering sets a new standard for precision chamfering. Unlike conventional machines that may struggle with unpredictable variables such as wheel wear or part inconsistencies, the MAX System Machine's patented compliant technology ensures consistent results every time, regardless of external factors. With a huge gain in efficiency, there is no loss in precision, there is quite the opposite. Even on small micro-parts, there is a visual difference when the part is finished on a James Engineering machine. Intricate and oddly shapen parts are also still finished with perfect chamfers and radiuses. These precision finishes minimize part wear and stress points to the fullest extent. 

Sustainability

Sustainability is a must in modern manufacturing, and the MAX System Machine delivers on this as well. Programmable cycles, which can be saved as "recipes," ensure perfect cycles every time, eliminating scraped parts and optimizing resources. With optional “wet” cycles, these MAX System machines are equipped with a 150-gallon tank that is filtered and recycled into the next cycle, maximizing the use of the water. Additionally, James Engineering produces their own grinding wheels with a liquid resin that extends part life and promotes even wear. Paired with compliant technology, that won’t over-engage tools, the life of the grinding wheels and various tool heads is greatly extended, further enhancing sustainability efforts.

An Automatic Chamfer Machine like no other

The MAX System Machine by James Engineering remains an industry leader in chamfering and finishing technologies, continuing to advance the manufacturing process. By seamlessly integrating efficiency, precision, and sustainability into a single, innovative solution, the MAX System Machine allows manufacturers to elevate their chamfering and finishing operations to new heights of performance and excellence.

If you’d like to know more reach out and learn how James Engineering can upgrade and take your manufacturing process to the next level. Watch our machine in operation below and see our technologies in action. 

In the intricate realm of manufacturing, achieving precision in part finishing is an ongoing pursuit that directly influences the quality and functionality of the final product. This comprehensive guide explores the common challenges encountered in part finishing and offers valuable insights into overcoming these hurdles with the help of advanced deburring and chamfering machines. Let's embark on a journey to master precision in part finishing.

1. Unwanted Burrs and Sharp Edges

Solution: Unwanted burrs and sharp edges can be effectively removed through various methods. Manual tools like files, abrasive brushes, and rotary deburring tools offer precision, while techniques such as abrasive blasting, chemical deburring, and thermal methods provide automated solutions. Advanced approaches like electrochemical deburring, cryogenic methods, waterjet cutting, and laser deburring cater to specific needs, emphasizing the importance of selecting the most suitable method based on material, part complexity, and production requirements.

2. Inconsistent Surface Finish:

Solution: Achieving a consistent surface finish is crucial for quality standards because it directly impacts the appearance, functionality, and performance of a finished product. Consistency ensures uniformity in texture and appearance, which is especially important in industries where aesthetics matter, such as automotive, aerospace, or consumer electronics. Additionally, a consistent surface finish is indicative of precision and attention to detail in manufacturing processes, reflecting a higher level of quality and meeting the stringent standards expected by customers and industry regulations. In applications where friction, wear, or corrosion resistance are critical factors, a uniform surface finish is essential for optimal performance and longevity of the final product. Overall, consistency in surface finish contributes to the reliability, durability, and overall quality of the manufactured components or products.

3. Material Compatibility:

Solution: Versatile machines handle various materials, ensuring adaptability and consistent finishing.

4. Complex Geometries:

Solution: Advanced machines with multi-axis capabilities navigate complex shapes with precision.

5. Efficiency and Speed:

Solution: High-speed deburring machines with multi-axis control significantly reduce processing times without compromising quality.

Conclusion:

In the complex landscape of part finishing, mastering precision requires overcoming various challenges. Advanced deburring and chamfering machines, exemplified by The MAX, offer practical solutions to elevate your manufacturing process. By integrating these technologies, you can navigate the intricacies of part finishing with confidence, achieving not only precision but also efficiency and sustainability. Explore the transformative potential of advanced machinery and stay ahead in the pursuit of mastering precision in manufacturing.

 Contact us for more information on 11-axis machining. Sales@James-Engineering.com

The Colorado-based OEM shop is known for their one-of-a-kind deburring and chamfering machines, but they also have a precision-focused machine shop that’s willing to take on any project that comes their way. If you’re in the market for a low to medium volume machine shop who guarantees quality products, reach out to James Engineering today at (303) 444-6787.

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What is our shop capable of?

Dave: We have 3 mills and 2 lathes. One of the mills has 4th axis capability. We’re capable of holding concentricity within 5/10ths in most cases without have to do any crazy set ups. We can do round parts, square parts, just about any shape part that you want.

Scott: We’ve got a live tool lathe with a bar feed option and multiple seats of programming software. We’ve got that 4th axis mill, another smaller mill with a 20-inch bed, and we’ve got a 60-inch bed large mill.

How many parts a week do we typically make?

Dave: That’s pretty subjective because we do short run production, so most of our time isn’t spent making parts, it’s getting ready to make a part and getting a part set up to run. Typically, we could spend half hour programming, half our setting up, and basically we could run for 15 minutes and then be done (in some cases). We can’t really quantify the quantity of parts per week because we’re more set up to be a tooling or prototype shop versus a production shop.

Can customers send in their own designs?

Dave: We quote on stuff and have stuff made for outside companies. We have engineering services, so people can send in a concept and we could do the whole thing, or they could send in a thing that’s basically done and we could create drawings for them, things like that. We have start-to-finish capability, or we can pick up a project that they’re already halfway through. We can also provide good drawings, give them a model.

What are some basic jobs we do frequently?

Dave: We do a lot of gun parts, automotive stuff, motorcycle parts. It really is just a gamble. Basically, anybody who walks into the door with a project, we can take a look at it and see if it fits our capabilities fairly easy and we’ll do it. We’ve done a lot of welding jobs lately, too. We’ve done a lot of stuff for RoboCon; we’ve made a lot of platforms and fixturing.  We’ve made brownie bowls, and stuff for volleyball companies, it doesn’t really matter what industry comes in.

Scott: So we’ve got a lot of high end, high precision parts that we make. For example, we’re making a mount for a vehicle right now. Our perfect job is a volume job. We’re really looking for anything from prototype to a few thousand parts a week. I wouldn’t call ourselves high volume where we’re tens of thousands of parts per week, but we’re definitely looking for that low to medium volume area.

What makes our shop stand out?

Dave: Our attention to detail and the quality of our parts. That’s something that we take a lot of pride in. We try to go that one step above, whether it’s by deburring or not putting a scratch on it by pushing it across surfaces, things like that. We take really good care of all the parts we make, and it’s a lot easier to go in and get the quality you’re looking for when you’re not making thousands and thousands of parts.

Why is it significant for our machine side of business that we make our own parts in-house?

Dave: We can control our own quality because our standards are really high. To be able to get the tolerances and stuff we need we can hardly get other people to make them for us. We put a dimension on a drawing and expect you to hold it, so in some cases we put really tight tolerances on things with reason, and when other companies see those tight tolerances the cost goes up automatically (whether it’s justifiable or not). It’s more cost efficient for us to do it.

Scott: We have to make all of these parts here in-house because we really can’t afford to job much of this out. We’ve got to keep our profit margins where they need to be. We have to hold pretty precision fits because we’ve got a 3.2 million resolution encoder here turning all of these [parts] on this five-axis manipulator.

How do your own deburring machines fit into the machine shop process?

Scott: When we make these parts, we do a lot of in-machine deburring. We’ll go through and we’ll machine this edge with a chamfer tool. But the problem is, when we machine the edge with the chamfer tool, the chamfer tool creates two sharp edges. We still have this problem where a technician has to go in with Scotch-Brite and deburr this. So we don’t want that abrasive to get into our CNC machine, because if that abrasive gets into our machines, it gets down into ways and slides and it wears the machine out. That’s where the market is for our deburring machine.

Simply put, the process of chamfering is cutting a 90-degree edge at a 45-degree angle as a way to remove stress-rising sharp edges, as well as allow for smoother assembly. That makes chamfering sound easy, when in reality it’s actually very time consuming, no matter the method of approach.

Gear Chamfering can truly be broken down into four separate surface-finishing processes: deburring, chamfering, radiusing, and radius-chamfering.

-       Deburring is the process of grinding off burrs, which are bits of excess metal created in the metal cutting process. Burrs are extremely problematic and will cause issues in assembly as well as overall part efficiency. Assuming the deburring has been done properly, all burrs will have been completely removed, leaving nothing but a sharp edge.

-       Chamfering, as stated above, is the process of cutting that sharp edge at a 45-degree angle (which is the most common angle, but not the only one they’re limited to). Chamfering can be done with a myriad of tools, such as brushes, sandpaper, grinding wheels, and Scotch-Brite. However, in the process of shaving down this one sharp edge, two more are created on either side of the original, and if the tool being used is worn down, burrs can be created as well.

-       Radiusing is the process of completely rounding out edges until it’s completely smooth. While chamfering is smoother than just leaving a part deburred, it still is cut at a noticeable angle that can be seen and felt. Radiusing feels and looks rounded (just like how a ball is round without any hard edge), and can also be carried out via brushes, grinding wheels, and sandpaper. It’s crucial to know what materials these tools are made out of, because the materials will affect the quality of the radius; if a material is too abrasive, it will be impossible to reach a true radius. A true radius is when the edges of a 90-degree angle go tangent to tangent without any surface imperfection.

-       Radius-chamfering is when a part receives both radiusing and chamfering. The sharp angle is cut at the usual 45-degree angle, and when those two extra sharp angles are created, they are radiused to create smooth transitions between chamfers.

When it comes to how chamfering is done, there’s a few methods operators can choose from—machine-based, hand-based, or robot-based.

Different types of gear chamfering machines are capable of different sub-categories of chamfering. For example, a CNC machine can decently deburr a part, a lathe can adequately radius-chamfer a part, and a mill can chamfer a part. All of these options are valid, but not a single one of them can chamfer, deburr, and radius a part; separate machines are needed. Not only that, but these kinds of machines require in-depth programming for every single part in order to be exact. The MAX by James Engineering is capable of carrying out all four chamfering processes with heightened precision, as well as little programming.

Doing any of these processes by hand is technically achievable, but it ultimately proves to be more troublesome than it’s worth. Manufacturing is an industry that requires precision, as things will fall apart and fail to work correctly without it, and doing these processes by hand simply does not provide adequate enough precision. Even the best operator can slip or tremble, and man cannot repeatably guarantee a consistent chamfer. Hand chamfering is acceptable in a pinch, especially if only one or a handful of parts require it. But for higher volume operations, not only does hand chamfering not produce consistent results, it also is extremely time and cost inefficient. Scrap rates are the highest with hand chamfering, and the time it takes operators to complete one part is what it would take a CNC to do two or three, or the MAX to do a hundred.

Robots are only slightly better at gear chamfering than when done by hand. While they do have better mobility than most machines, they lack precision. Robots are perfect for operations that require the moving and placing of items, but they just cannot match a machine’s precision. Robots also require a lot of laborious programming, overall making them a poor method of chamfering.

Out of all these methods, the MAX is hands down the most reliable and efficient. As an all-encompassing finishing system, it is capable of deburring, chamfering, radiusing, and radius-chamfering any part or gear, no matter its complexity. It does require some initial programming, but once a part/gear has been loaded in, the MAX will remember it for future use, meaning operators no longer have to manually input adjustments themselves (James Engineering calls these programs “recipes”). The MAX is also capable of repeatable precision down to the fifth decimal. For reference, the average human hair measures to .003 inches. The MAX can repeatably work down to .00001 inches, and even beyond that.

Precision in chamfering is key, because the less precise a chamfer is, it’s more likely that stress risers will appear with continual usage. Stress risers are tiny cracks that form at a part/gear’s weakest point of contact (like the tooth on a gear). If a part is not adequately deburred or chamfered, what will happen is those sharp edges will slowly break off until a part or gear’s structure is ultimately compromised. So that previously mentioned tooth could fall off, for instance. That is extremely dangerous, both for the assembly itself and the people operating it. For example, a helicopter would crash if one of the gears in its motor failed. When it comes to chamfering, the higher the precision, the better. The precision achieved by the MAX means that parts/gears processed through it are extremely unlikely to form stress risers even after years of use.

There’s a misconception about chamfering that it’s done easily. Even with an advanced machine such as the MAX, chamfering is no “easy” feat. If a chamfering operation appears to be “easy”, it’s probably being done sloppily and inefficiently—and precision takes time and effort.

Knowing the correct way to chamfer is a gamechanger with any operation, as well as being able to recognize when a chamfer is done correctly. If it is, parts will fit together with no resistance and work efficiently for the entirety of their lifetime. And when parts work correctly, overall assemblies will perform at their best.

To visibly see how chamfering is done, watch a short video clip here.
To contact James Engineering about the MAX’s chamfering abilities, call at (303) 444-6787

Every piece of machinery is made up of a thousand smaller pieces all continuously working together to accomplish the same goal. Every single one of these pieces need to go through the part finishing process, which ensures they work correctly and keep the overall operation running smoothly. “Part finishing” is an umbrella term for all the individual processes and techniques that go into the ultimate completion of these parts/gears.

Machining

First, let’s start with machining. This is where gears/parts are initially manufactured out of blocks of raw material. CNC (computer numerical control) machines do most of this work, and there are multiple different kinds of CNC machines, such as milling machines, lathes and turning machines, laser cutting machines, etc. Excess material is carved away by these machines to reveal the rough shape of whatever gear/prismatic part is being created. Once this first step is completed, the nitty-gritty side of part finishing begins.

Deburring

Deburring is the process of removing burrs from the edges and surfaces of these freshly cut parts/gears. Burrs are sharp bits of excess metal that will eventually ruin the integrity and overall quality of whatever part/gear they’re stuck to. This process can be done by hand, in a CNC machine, or a machine made specifically for deburring*, such as a James Engineering machine. Deburring is one of the most crucial aspects of part finishing, as many other processes cannot be done if a part or gear is not deburred properly.

Surface Grinding

This process creates smooth surface finishes on metal and non-metal parts alike. It’s an abrasive process which uses grinding wheels to shave down any surface impurities that might affect the functionality and aesthetic of a gear/part. Grinding wheels (add link to website page here) come in a variety of sizes and materials, which directly determine a wheel’s grinding intensity. Grinding surfaces are crucial when it comes to achieving tight part tolerances, as it ensures a part will fit perfectly within its environment. Surface grinding will also rid a part/gear of any corrosive layers that may negatively affect its overall durability.

Polishing

Polishing is done to further smoothen a part’s surface. What makes polishing different from surface grinding is that it’s meant to enhance surface quality, whereas grinding is used to remove extra material. Polishing is also an abrasive process, and it uses polishing pastes and abrasive pads. Polished parts are reflective and more resistant to corrosion, which makes it a crucial step in the finishing process for items such as car bumpers, medical equipment, mirrors, and more.

Buffing

Many people get buffing and polishing confused—but it’s fair considering how alike these two processes are. What makes them different is their levels of aggression. Buffing is the more aggressive of the two, and can actually remove surface material if done too hard. It can be used to remove shallow scratches, and unlike polishing, it will not leave a highly reflective surface. Buffing is frequently used in the automotive, jewelry, and electronic industries.

Chamfering

This step of the part finishing process is extremely important, especially for pieces with right-angled edges. Chamfering is when these edges are cut at a slope, which later makes assembly easier and reduces the amount of stress risers within a gear/part. Sharp, non-chamfered edges can snap and break off, leading to loose material floating throughout a machine. This debris could ultimately affect the efficiency of the entire machine, and even cause it to fail completely. When edges are chamfered, the likelihood of such an occurrence is reduced drastically. It will also ensure that pieces fit together more snugly, reducing the risk of the parts themselves becoming too loose.

Brushing

Brushing can be categorized as a type of deburring, as it can technically get rid of excess burrs left on the surfaces of parts. But that’s not its man job—brushing is used as a way to further perfect part surfaces, as it preps parts for coatings and rids them of any external contaminants, such as oils, dirt, residue, etc. It is also a very precise process in the sense that if only one small section of a part/gear needs further surfacing, a brush can stay focused on that specific spot without affecting the rest of the gear/part’s body. An important thing to remember when it comes to metal brushing is that certain brushes must be used on certain metals; for example, stainless steel can only be brushed with steel brushes. But other materials, such as rubber and leather, can also be brushed if need be.

Sandblasting

This process is also known as abrasive blasting, as it can be done with many other substances other than sand, such as glass beads, water, dry ice, and compressed air. This is another technique used to smoothen, decontaminate, and shape surfaces. This technique of part finishing comes from the naturally occurring phenomenon called aeolian erosion, which is when an environment’s geography is changed and shaped by consistent winds. Blasting is done manually when a blasting substance is mixed with air in a pressurized chamber and dispensed through an abrasive-proof handheld nozzle.

Washing

The washing process works exactly how you’d think it would—a mixture of hot water, solvent, or washing fluid are dispensed either by hand or by a machine over freshly-processed parts to clean them of excess swarf. It’s important to wash parts of debris because, as mentioned above, debris can drastically decrease the effectiveness of a part/gear and the greater machine it was assembled into. In order to avoid corrosion or rusting, special fluids must be used to protect both the part being washed and the machine doing said washing.

Overall

Machining, deburring, chamfering, washing, brushing, surface grinding, polishing, buffing, and sandblasting are the most common part finishing processes in the manufacturing industry, but there are still a variety of methods used that were not mentioned. Each process has its own unique use, and it’s crucial that manufacturers understand what method will produce the strongest outcome for a part or gear.

How James Engineering Part Finishes

Here at James Engineering, we are experts when it comes to the varying methods of part finishing. We manufacture and sell all all-encompassing surface finishing and chamfering machine known as the MAX System, and it’s got you covered completely—the MAX can deburr, chamfer, wash, brush, and even radius parts/gears of various sizes. The best part is the MAX can carry out multiple processes at once, which exponentially cuts down on processing time and leads to a higher production volume.

If you’d like to experience the effortless efficiency of a multitasking finishing fiend, contact us at Sales@James-Engineering.com and we will send you a quote!

*For being such a vital part in the finishing process, deburring machines are an extremely niche market of their own. James Engineering specializes in deburring and chamfering machines and offers a variety of systems at competitive pricing. Click here to learn more about the different kind of systems we manufacture.

Sources

As the demand for parts grows exponentially within the manufacturing industry, so does the need for expert deburring and chamfering. James Engineering manufactures an all-purpose finishing system known as the MAX System that is meant to be paired with CNC machines to produce parts of the highest caliber.

“The MAX is meant to compliment CNC machines,” explains Scott Richards, Vice President of James Engineering. “The MAX allows CNC machines to do what they do best: make parts.”

While CNC machines can deburr parts, they tend to be choppy, aggressive, and slow at it; their primary function is to cut. This means high-volume shops are extremely limited when it comes to both the quality and quantity of parts they’re producing (that is if they rely on CNC machines to deburr as well). The MAX is the solution to this problem—it leaves cutting to the CNC machines and does everything else. “We’re not trying to make a metal cutting machine, or a part manipulator. We’re making a machine that does a delicate job quickly in a way that hand deburring, and CNC machines, can’t,” says Richards. So once the CNC machines can focus solely on cutting, a higher volume of parts can be produced in one day, ultimately heightening a company’s productivity as well as increasing their overall part quality.

Not only does the MAX make overall processing easier, but the machine itself is easily operatable, especially for those who have prior experience with CNC machines. “Within four minutes anybody could learn how to use the machine,” Richards states, “We teach these machines to move into position conversationally, have it catch that point, then move to another position. This is unlike CNC machines, or even robots. If someone new wanted to run a CNC machine, they’d have to understand the language the program is written in; we do not run M- or G-code, we use conversational programming.”

Deburring in a CNC machine can be inaccurate and slow-moving—but that’s because deburring isn’t the main function of a CNC, cutting is. The whole purpose of the MAX is to take the weight of deburring off CNC machines. So while the CNCs focuses on expertly cutting parts, the MAX deburrs, chamfers, brushes, washes, and surfaces all in one go after said parts have gone through the CNC. The MAX will pick up a CNC’s slack, and vice versa, making them the perfect pair. The duo will drastically reduce cycle times while still producing a high volume of expertly processed parts with focus, and without the sacrifice of integrity. For any shops out there running into issues with CNC deburring, or for companies who would simply like to increase their productivity overall, investing in the MAX is the next step you need to make.

Everyone needs a best friend, even machines. Give your CNC its best buddy today and inquire at Sales@James-Engineering.com as to how you can bring your MAX home.

Grinding wheels are vital in the manufacturing world—they’re how machinists polish rough edges and achieve consistent chamfers. The size and abrasiveness of these wheels very depending on what materials they’re made of. This will directly correlate with what gears/parts the wheels are used for.

Here at James Engineering, we have an extensive stock of various grinding wheels and sell them at competitive prices. Let’s get into the 3 main wheels we sell and why you need to know the difference between them.

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1. The Woven Fiberglass Wheel

This is your typical grinding wheel made from a homogenous blend of aluminum oxide and powdered resin. The tops and bottoms of these wheels are pressed with fiberglass, which acts as a strengthening agent and ensures the wheels don’t break while spinning.

Pros: They’re quick, and they’re aggressive, meaning their time efficient and great for cutting.

Cons: They can sometimes be a little too aggressive. These wheels can cut too deeply and have an extreme tendency to bounce, as they have no dampening factor.

2. The Woven Cloth Wheel

This wheel is comprised of cotton, liquid resin, and aluminum oxide. You might be thinking, cotton, really? But it really works! Strips of cotton cloth are layered between layers of resin, and these many layers keep the wheel’s structure from falling apart.

Pros: These wheels are great for chamfering due to the fact they don’t bounce nearly as much as fiberglass wheels do since the cotton acts as a dampening agent. The fact that they’re softer, and don’t have as much bounce, means the parts/gears they’re working on can be spun at faster rates, achieving a quicker and smoother chamfer.

Cons: They’re a bit too soft for cutting. Believe it or not, cotton isn’t very sharp.

3. The Woven Carbon Fiber Wheel

This is the most unique wheel sold at James Engineering. In fact, it’s so unique and rare that we are the only ones to carry it! These wheels are made of carbon fiber and resin, and nothing more. There’s no abrasive added to them, but the carbon itself acts as a very mild abrasive.

Pros: They’re perfect for those with very niche needs. They create extremely subtle chamfers and have beautiful surfacing abilities. They’re also great to use at trade shows because they won’t tear apart gears or non-gears during demonstration.

Cons: They’re very, very gentle, so they can’t do very much. Since they have no abrasive added to them, they make cutting and grinding a drawn-out process—essentially, they’re mostly for people who need very petite chamfers.

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Whatever your grinding needs consist of, James Engineering will help you find the most perfectly-fitting wheel. We’ll even send you a sample or two!

 If you’re interested to know even more about the different kind of grinding wheels we sell, check out https://www.james-engineering.com/grinding-wheels.

Getting a perfect gear chamfer is not easy. In many cases, many people aren’t even aware that it could be done better; they probably don’t even know why they aren’t seeing better results.

There are many variables that affect the outcome of a chamfer: grinding wheel speed, grinding wheel pressure, grinding wheel angle, rotary table speed, etc. Keeping all these components in mind can be a headache! Who knew such a process could be so complicated?

Well, James Engineering has a couple of tips that will help you achieve the cleanest chamfer possible:

·      Make sure the grinding wheel engages the part gently. If it’s too quick in engaging, you might notice a small cloud of dust burst up from the point of contact, gouging the part in a way that is noticeable to the eye. This small cloud will contain 3 to 4 times more material removed in that single instant than what you’d see after chamfering the entire part!

·      Be sure that the grinding wheel produces an even spark pattern. Any interruption in that pattern is a loss in efficiency, and can be caused when the wheel lifts and bounces back down onto the part. Whether that bounce is subtle or extreme, it will still cause a decrease in wheel life and leave you with an inconsistent chamfer.

·      To eliminate heavy chamfer marks, or what we call striations, use a wheel that has natural shock-absorption, such as the wheel we sell at James Engineering. Most companies use rigid cutoff wheels made of fiberglass reinforcing material, bonded with a dense (and usually black) open-cutting resin. But we at James Engineering suggest using a reinforced open-cutting, resin-bonded wheel with shock-absorbing properties, which also happen to be a lighter color and won’t break when forced to flex slightly. The best way to see the difference between the two kind of wheels, other than overall performance, is to bounce the cutting edge of the wheel off your desk. The competing wheel will bounce instantly, while ours will absorb some of the impact’s shock and not bounce as wildly—it’ll even sound quieter!

If you implement these three tips, chamfering becomes a whole different animal. You’ll be able to hear the difference between a good and bad chamfer; the good will sound smooth, while the bad will sound choppy. You’ll be left with a chamfer so clean, so perfect, you won’t be able to help but call it the champion of all gear chamfers. If you have any questions, or would like to receive a wheel sample, please feel free to contact us at Sales@James-Engineering.com.