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Shining a Light on Diamond End Mills

Diamond tooling and diamond-coated end mills are a great option when machining highly abrasive materials, as the coating properties help to significantly increase tool life relative to uncoated carbide tools. Diamond tools and diamond-like coated tools are only recommended for non-ferrous applications, including highly abrasive materials ranging from graphite to green ceramics, as they have a tendency to break down in the presence of extreme heat.

Understanding the Properties of Diamond Coatings

To ensure proper diamond tooling selection, it’s critical to understand the unique properties and makeup of the coatings, as there are often several diamond coating variations to choose from. Harvey Tool, for example, stocks Amorphous Diamond, CVD Diamond, and PCD Diamond End Mills for customers looking to achieve significantly greater tool life when working in non-ferrous applications.

Diamond, the hardest known material on earth, obtains its strength from the structure of carbon molecules. Graphite, a relatively brittle material, can have the same chemical formula as diamond, but is a completely different material; while Graphite has a sp2 bonded hexagonal structure, diamond has a sp3 bonded cubic structure. The cubic structure is harder than the hexagonal structure as more single bonds can be formed to interweave the carbon into a stronger network of molecules.

diamond tool coatings

Amorphous Diamond Coating

Amorphous Diamond is transferred onto carbide tools through a process called physical vapor deposition (PVD). This process spreads a mono-layer of DLC coating about 0.5 – 2.5 microns thick onto any given tool by evaporating a source material and allowing it to condense onto that tool over the course of a few hours.

amorphous diamond coating

Chemical Vapor Deposition (CVD)

Chemical Vapor Deposition (CVD) is a coating process used to grow multiple layers of polycrystalline diamond onto carbide tooling. This procedure takes much longer than the standard PVD coating method. During the coating process, hydrogen molecules are dissociated from the carbon molecules deposited onto the tool, leaving a diamond matrix under the right temperature and pressure conditions. Under the wrong conditions, the tool may be simply coated in graphite. 6% cobalt carbide blanks allow for the best adhesion of diamond and a substrate. CVD diamond coated end mills have a typical thickness of coating that is between 8 and 10 microns thick.

CVD Diamond Coating

Polycrystalline Diamond (PCD)

Polycrystalline Diamond (PCD) is a synthetic diamond, meaning it is grown in a lab and contains mostly cubic structures. Diamond hardness ranges from about 80 GPa up to about 98 GPa. PCD end mills have the same diamond structure as CVD diamond tools but the binding technique is different. The diamond starts in a powdery form that is sintered onto a carbide plate using cobalt as a solvent metal substrate. This is done at an extreme temperature and pressure as the cobalt infiltrates the powder, causing the grains to grow together. This effectively creates a thick diamond wafer, between 010” and .030” in width, with a carbide base. This carbide base is then brazed onto the head an end mill and sharpened.

PCD Diamond CoatingHow Diamond Coatings Differ

Coating Hardness & Thickness

Polycrystalline tools (CVD or sintered) have a much higher hardness, thickness, and max working temperature than Amorphous Diamond oated tools. As mentioned previously, a PCD tool consists of a diamond wafer brazed to a carbide body while a CVD tool is a carbide end mill with a relatively thick layer of polycrystalline diamond grown into it. This grown layer causes the CVD tools to have a rounded cutting edge compared to PCD and Amorphous Diamond coated tools. PCD tools have the thickest diamond layer that is ground to a sharp edge for maximum performance and tool life. The difference between PCD tools and CVD coated tools lies in the thickness of this coat and the sharpness of the cutting edge. Amorphous Diamond tools maintain a sharper edge than CVD coated tools because of their thin coating.

Flute Styles

Harvey Tool’s line of PCD end mills are all straight fluted, CVD coated tools are all helically fluted, and Amorphous Diamond tools are offered in a variety of options. The contrast between straight fluted and helically fluted can be seen in the images below, PCD (top) and CVD (bottom). Electrical discharge machining, grinding or erosion are used cut the PCD wafer to the specifications. The size of this wafer limits the range of diameters that can be achieved during manufacturing. In most situations a helically fluted tool would be preferred over a straight fluted tool but with true diamond tooling that is not the case. The materials that PCD tools and CVD coated tools are typically used to cut produce a powdery chip that does not require the same evacuation that a metallic or plastic chip necessitates.

PCD Diamond end mill

PCD Ball End Mill

CVD Diamond end mill

CVD Ball End Mill

Proper Uses

CVD tools are ideally suited for abrasive material not requiring a sharp cutting edge – typically materials that produce a powdery chip such as composites and graphite. Amorphous Diamond tools have a broad range of non-ferrous applications spanning from carbon fiber to precious metals but ceramics are typically outside their range as they can be too abrasive and wear away the coating. PCD tools overlap their CVD and DLC coated counterparts as they can be used for any non-ferrous abrasive material.

Cut to the Point

Harvey Tool carries physical vapor deposition diamond-like carbon coated tools, chemical vapor deposition diamond tools and polycrystalline diamond tools. PCD tools are composed of the thickest diamond wafer brazed onto a carbide shank and are ground to a sharp edge. CVD coated tools have the diamond grown into a carbide end mill. Amorphous Diamond coated tools have the DLC coated onto them through the PVD process. For more information on the diamond coating best suited for your operation, contact a Harvey Tool Tech Team Member for immediate help.

Tool Deflection & Its Remedies

Every machinist must be aware of tool deflection, as too much deflection can lead to catastrophic failure in the tool or workpiece. Deflection is the displacement of an object under a load causing curvature and/or fracture.

For Example: When looking at a diving board at rest without the pressure of a person’s weight upon it, the board is straight. But as the diver progresses down further to the end of the board, it bends further. Deflection in tooling can be thought of in a similar way.

Deflection Can Result In:

  • Shortened tool life and/or tool breakage
  • Subpar surface finish
  • Part dimensional inaccuracies

Tool Deflection Remedies

Minimize Overhang

Overhang refers to the distance a tool is sticking out of the tool holder. Simply, as overhang increases, the tool’s likelihood of deflection increases. The larger distance a tool hangs out of the holder, the less shank there is to grip, and depending on the shank length, this could lead to harmonics in the tool that can cause fracture. Simply put, For optimal working conditions, minimize overhang by chucking the tool as much as possible.

extended reach tool

Image Source: @NuevaPrecision

Long Flute vs. Long Reach

Another way to minimize deflection is having a full grasp on the differences between a long flute and a long reach tool. The reason for such a difference in rigidity between the two is the core diameter of the tool. The more material, the more rigid the tool; the shorter the length of flute, the more rigid the tool and the longer the tool life. While each tooling option has its benefits and necessary uses, using the right option for an operation is important.

The below charts illustrate the relationship between force on the tip and length of flute showing how much the tool will deflect if only the tip is engaged while cutting. One of the key ways to get the longest life out of your tool is by increasing rigidity by selecting the smallest reach and length of cut on the largest diameter tool.

tool deflection

 

tool deflection

 

When to Opt for a Long Reach Tool

Reached tools are typically used to remove material where there is a gap that the shank would not fit in, but a noncutting extension of the cutter diameter would. This length of reach behind the cutting edge is also slightly reduced from the cutter diameter to prevent heeling (rubbing of noncutting surface against the part). Reached tools are one of the best tools to add to a tool crib because of their versatility and tool life.

 

When to Opt for a Long Flute Tool

Long Flute tools have longer lengths of cut and are typically used for either maintaining a seamless wall on the side of a part, or within a slot for finishing applications. The core diameter is the same size throughout the cutting length, leading to more potential for deflection within a part. This possibly can lead to a tapered edge if too little of the cutting edge is engaged with a high feed rate. When cutting in deep slots, these tools are very effective. When using HEM, they are also very beneficial due to their chip evacuation capabilities that reached tools do not have.

 

Deflection & Tool Core Strength

Diameter is an important factor when calculating deflection. Machinists oftentimes use the cutter diameter in the calculation of long flute tools, when in actuality the core diameter (shown below) is the necessary dimension. This is because the fluted portion of a tool has an absence of material in the flute valleys. For a reached tool, the core diameter would be used in the calculation until its reached portion, at which point it transitions to the neck diameter. When changing these values, it can lower deflection to a point where it is not noticeable for the reached tool but could affect critical dimensions in a long flute tool.

Deflection Summarized

Tool deflection can cause damage to your tool and scrap your part if not properly accounted for prior to beginning a job. Be sure to minimize the distance from the tool holder to the tip of the tool to keep deflection to a minimum. For more information on ways to reduce tool deflection in your machining, view Diving into Depth of Cut.

5 Ways Your Shop is Inefficient

5 Ways Your Shop is Inefficient

In today’s ultracompetitive industry, every machine shop seeks even the slightest edge to gain an advantage on their competition and boost their bottom line. However, what many machinists don’t know is that improving their shop’s efficiency might be easier than they thought. The following five ways your shop is inefficient will provide a clear starting point of where to look for machinists desperate to earn a competitive edge.

1. Premature Tool Decay / Tool Failure

If you’re finding that your tools are failing or breaking at an unacceptable rate, don’t mistake it for commonplace. It doesn’t have to be. Prolonging the life of your tooling starts with finding not just the right tool, but the best one; as well as running it in a way to get its optimal performance. Many machinists mistake premature tool failure with running parameters that were too aggressive. In fact, not pushing the tool to its full potential can actually cause it to decay at an accelerated rate in certain situations.

Tool failure can occur in many different ways: Abrasive Wear, Chipping, Thermal Cracking or Tool Fracture, just to name a few. Understanding each type and its causes can help you to quickly boost your shop’s efficiency by minimizing downtime and saving on replacement tool costs.

tool wear

An example of a tool with excessive wear

For more information on tool wear, view Avoiding 4 Major Types of Tool Wear.

2. Subpar Part Finish

Your shop spends money to employ machinists, run machines, and buy cutting tools. Get your money’s worth, lead the industry, and ensure that you’re providing your customers with the highest quality product. Not only will this help to keep your buyer-seller relationship strong, but it will allow you the flexibility to increase your prices in the future, and will attract prospective customers.

Many factors influence part finish, including the material and its hardness, the speeds and feeds you’re running your tool at, tool deflection, and the tool-to-workpiece orientation.

For more information on ways to improve your part finish, view our Part Finish Reference Guide.

3. Inefficient Coolant Usage

One often forgotten expense of a machine shop is coolant – and it can be pricey. A 55-gallon drum of coolant can run more than $1,500. What’s worse is that coolant is often applied in excess of what’s required for the job. In fact, some machines even feature a Minimum Quantity Lubricant (MQL) functionality, which applies coolant as an extremely fine mist or aerosol, providing just enough coolant to perform a given operation effectively. While drowning a workpiece in coolant, known as a “Flood Coolant,” is sometimes needed, it is oftentimes utilized on jobs that would suffice with much less.

For more information about coolants and which method of application might be best for your job, view What You Need to Know About Coolant for CNC Machining.

4. Not Taking Advantage of Tool Versatility

Did you know that several CNC cutting tools can perform multiple operations? For example, a Chamfer Mill can chamfer, bevel, deburr, and countersink. Some Chamfer Mills can even be used as a Spotting Drill. Of course, the complexity of the job will dictate your ability to reap the benefits of a tool’s versatility. For instance, a Spotting Drill is obviously the best option for spotting a hole. If performing a simple operation, though, don’t go out of your way to buy additional tooling when what’s already in your carousel can handle it.

chamfer mills

To learn more about versatile tools that can perform multiple applications, check out Multi-Functional Tools Every Shop Should Have.

5. High Machine Downtime

What use is a machine that’s not running? Minimizing machine downtime is a key way to ensure that your shop is reaching its efficiency pinnacle. This can be accomplished a variety of ways, including keeping like-parts together. This allows for a simple swap-in, swap-out of material to be machined by the same cutting tool. This saves valuable time swapping out tooling, and lets your machine to do its job for more time per workday. Production planning is a key factor to running an efficient machine shop.

The Advances of Multiaxis Machining

CNC Machine Growth

As the manufacturing industry has developed, so too have the capabilities of machining centers. CNC Machines are constantly being improved and optimized to better handle the requirements of new applications. Perhaps the most important way these machines have improved over time is in the multiple axes of direction they can move, as well as orientation. For instance, a traditional 3-axis machine allows for movement and cutting in three directions, while a 2.5-axis machine can move in three directions but only cut in two. The possible number of axes for a multiaxis machine varies from 4 to 9, depending on the situation. This is assuming that no additional sub-systems are installed to the setup that would provide additional movement. The configuration of a multiaxis machine is dependent on the customer’s operation and the machine manufacturer.

Multiaxis Machining

With this continuous innovation has come the popularity of multiaxis machines – or CNC machines that can perform more than three axes of movement (greater than just the three linear axes X, Y, and Z). Additional axes usually include three rotary axes, as well as movement abilities of the table holding the part or spindle in place. Machines today can move up to 9 axes of direction.

Multiaxis machines provide several major improvements over CNC machines that only support 3 axes of movement. These benefits include:

  • Increasing part accuracy/consistency by decreasing the number of manual adjustments that need to be made.
  • Reducing the amount of human labor needed as there are fewer manual operations to perform.
  • Improving surface finish as the tool can be moved tangentially across the part surface.
  • Allowing for highly complex parts to be made in a single setup, saving time and cost.

9-Axis Machine Centers

The basic 9-axis naming convention consists of three sets of three axes.

Set One

The first set is the X, Y, and Z linear axes, where the Z axis is in line with the machine’s spindle, and the X and Y axes are parallel to the surface of the table. This is based on a vertical machining center. For a horizontal machining center, the Z axis would be aligned with the spindle.

Set Two

The second set of axes is the A, B, and C rotary axes, which rotate around the X, Y, and Z axes, respectively. These axes allow for the spindle to be oriented at different angles and in different positions, which enables tools to create more features, thereby decreasing the number of tool changes and maximizing efficiency.

Set Three

The third set of axes is the U, V, and W axes, which are secondary linear axes that are parallel to the X, Y, and Z axes, respectively. While these axes are parallel to the X, Y, and Z axes, they are managed by separate commands. The U axis is common in a lathe machine. This axis allows the cutting tool to move perpendicular to the machine’s spindle, enabling the machined diameter to be adjusted during the machining process.

A Growing Industry

In summary, as the manufacturing industry has grown, so too have the abilities of CNC Machines. Today, tooling can move across nine different axes, allowing for the machining of more intricate, precise, and delicate parts. Additionally, this development has worked to improve shop efficiency by minimizing manual labor and creating a more perfect final product.

Aspex CNC – Featured Customer

Aspex CNC is a CNC machine shop based out of Poway, California. They offer prototype turning and milling, as well as production level machining. Their quick turnaround times and premium quality have garnered them some serious recognition in the manufacturing industry. Aspex CNC is just one of the four businesses that Gary Colle Jr. currently owns, but they are an essential part of his business ecosystem, creating parts for the other three product-based companies while also offering machining services to outside customers.

We talked to Gary about his unique experiences in the industry, his thoughts on 5 axis machining, his advice for trying High Efficiency Milling, and more!

Tell us a bit about how you got started in machining, your businesses, and how Aspex CNC was formed.

It is a bit of an interesting story. I got started in manufacturing because my father designed, developed, and manufactured one of the first lines of Wheelchair Accessible Vehicle lifts, which allow people in wheelchairs to easily get in and out of their vehicles. The company was called GoldenBoy Mobility and is still one of the four business I currently own and operate today.

At a young age, I was working in my father’s shop, answering phones and doing odd jobs as young as the age of 10. When I got to high school, I worked after school and during the summers in a more hands-on position, welding parts, cutting up cars, and helping on the shop floor. This really inspired my love for metalworking at a young age.

goldenboy mobility

My dad used to let me mess around in the shop at night, so I started welding my own parts and trying to learn as much as I could. One day, someone came in and asked if I could create a “tuna tower” (an accessory for wakeboarding/water skiing) for their boat. I relented at first, but eventually gave in and welded all the parts together for him. After I made that one, word got around that I could create these at night. I started to advertise a little bit locally, and people started ordering more and more. That summer, I ended up making 50 of these towers and got noticed by a couple of big distributors. Scaling up like that made it necessary to outsource some of our parts to local machine shops, which is where I discovered machining. I had very little prior knowledge of machining, but once I stepped into my first machine shop, I was blown away.

As that business grew even larger (now known as DBG Concepts), I needed more parts and needed them faster. We outgrew the local shops and purchased our first machine, a Fadal 4020 CNC Mill, from a local machine salesman, who also helped teach me the ropes. I learned a lot in those first 6 months about machining.

Business kept ramping up, and my father eventually retired and I took over GoldenBoy Mobility. With all the extra parts we needed, we kept machining things in-house, and buying more mills. Eventually, machining became an even larger part of the business than either DBG Concepts or GoldenBoy Mobility, so we formed Aspex CNC to move our machining out of the product line and more into prototype work and production machining for other business. We still machine most of the parts for DBG and GoldenBoy in-house, but we are doing much more for outside sources than we used to.

What sort of machines do you use in your shop?

Right now, we are a Haas-only shop. We currently have eight Haas machines in our shop. Our lineup consists of a couple of lathes (ST10 and ST30), a Super Mini Mill, and five CNC Mills (VF2SS, VF2SSYT, VF4SS, VF5SS, and UMC750SS), with another UMC750 on the way!

aspex cnc

Which materials do you most often work with in your shop?

We work with a lot of the common materials, 6061/7075 Aluminum, 1018/1045 Steel, 303/304/17-4ph Stainless, as well as plastics like Acetal, UHMW, HDPE, and PVC.

How has your experience been with 5 axis machining?

If you don’t keep up with technology, you won’t be able to keep up with business, so learning multi-axis machining was a no-brainer for us. We first started with a Haas HRT210 4th axis rotary, and began to play with that. Over the next two years, we learned everything we could about multi-axis machining and made the decision to upgrade to a 5 axis machine. We actually went to IMTS that year to talk to manufacturers and find the perfect machine for us and ended up sticking with Haas because of their support platform and educational resources.

5 axis can be hard, but there are a lot of tools out there (HSM Works from Autodesk being one) that can help you learn. It does require a little more upfront work and discipline, but it eliminates a lot of setup time, creates new opportunities for our shop, and has been really good for us from a business standpoint. A big part of our business is machining one-off parts, so the 5 axis machine allows for a faster turnaround time for those odd shapes and sizes we come across.

5 axis machining

You are very active on social media promoting your business. How has the online machinist community helped your business?

Honestly, even though it can become a bit of a distraction at times, using social media to share our work and partner up with companies like Harvey Tool and Helical has been a lot of fun. We are still young in the social media space, so we haven’t seen a massive impact yet, but the best is yet to come. We have received a few bites here and there which has led to work, but as with everything, it takes some time. We expect a lot of growth this year as we work on more really neat projects and continue to get our name out there. As we grow, the opportunities are going to come.

aspex cnc

What are some of the coolest projects you have ever worked on?

Unfortunately, we can’t talk about most of the work we do, due to customer confidentiality, but we did just do a project for the State of California building a training vehicle for their driver’s education program. We designed and built a dual steering system that gave the driver’s trainer a second steering wheel on the passenger side of the car to be used during training. Another job we just finished up was some parts for the new Raiders football stadium in Las Vegas. They contacted us in a pinch and needed them in two days, and we made it happen. It is pretty cool to know you played a part in a huge project like that.

Aspex CNC also does a lot of work with racing/off-road vehicle companies, often machining parts for the chassis and suspension components. We have worked on projects for companies like Scarbo Performance, ID Designs, TSCO Racing and a whole list of others.

You can only use one machine for the rest of your life. Do you go with a CNC Milling machine or the Lathe?

I would hate to have to choose between them, but it is 100% the CNC Mill. I love ripping around with end mills and working with the 5 axis machines. It is mind blowing what these things are capable of.

Why is manufacturing products in America important to you?

Growing up in the industry which I did while working under my father (building wheelchair accessible vehicles), we had a lot of customers who were veterans coming back from Vietnam or Desert Storm who had been injured overseas and needed extra accommodations, which we could provide for them. The veterans I have worked with made me so patriotic with their stories and courage. We also get to work on a lot of projects with the US Department of Veteran’s Affairs, which is putting money back into the American economy by supporting companies like ours and contracting us to make these vehicles. It only makes sense that we employ more people here and avoid sending things overseas to support those who have supported us.

aspex cnc

Do you utilize High Efficiency Milling (HEM) techniques in your shop? What advice do you have for those who are getting started with HEM?

Absolutely, all the time!

The biggest thing is listening to your tool manufacturer for recommendations and then cut those in half to start. From there, work your way up until you are comfortable. Just because the tool can handle it doesn’t necessarily mean your machine, work holding and or set up can, so I would advise people to walk before you run when it comes to HEM.

If you could give one piece of advice to a new machinist ready to take the #PlungeIntoMachining, what would it be?

Be conservative and establish good habits from the start. You can get more aggressive as your career starts to take off, but don’t run out and try to run the biggest and baddest machines on day one and try to cut corners. You need to learn what is behind machining; you can get easily lost in all the technology that is available, but you need to understand the core science behind it first. Take it slow, because if you go too fast, you might miss something important along the way.

Is there anything else you would like to share with the In The Loupe community?

The best thing is building relationships with companies like Haas, Harvey Tool, and Helical. Not only do they provide great service and support for you, but it quickly becomes a mutually beneficial relationship. As we give feedback to the tool and machine manufacturers, and even our metal supplier, it helps them improve their products, which in turn allows our shop to increase our production and efficiency.

Also, having a good team with good people makes all the difference. No matter how many machines you have and how automated you get, you still need good people on your side. I would put my guys up against any other machine shop out there in terms of skill, and it is a big part of what has made our business so successful.

aspex cnc


Would you like to be considered for a future “Featured Customer” blog? Click here to submit your information.

Optimizing Material Removal Rates

 What is the Material Removal Rate?

Material Removal Rate (MRR), otherwise known as Metal Removal Rate, is the measurement for how much material is removed from a part in a given period of time. Every shop aims to create more parts in a shorter period of time, or to maximize money made while also minimizing money spent. One of the first places these machinists turn is to MRR, which encompasses Radial Depth of Cut (RDOC), Axial Depth of Cut (ADOC), and Inches Per Minute (IPM). If you’re aiming to boost your shop’s efficiency, increasing your MRR even minimally can result in big gains.

Calculating MRR

The calculation for Material Removal Rate is RDOC x ADOC x Feed Rate. As an example, if your RDOC is .500″, your ADOC is .100″ and your Feed Rate is 41.5 inches per minute, you’d calculate MRR the following way:

MRR = .500″ x .100″ x 41.5 in/min = 2.08 cubic inches per minute.

Optimizing Efficiency

A machinists’ depth of cut strategy is directly related to the Material Removal Rate. Using the proper RDOC and ADOC combination can boost MRR rates, shaving minutes off of cycle times and opening the door for greater production. Utilizing the right approach for your tool can also result in prolonged tool life, minimizing the rate of normal tool wear. Combining the ideal feed rate with your ADOC and RDOC to run at your tool’s “sweet spot” can pay immediate and long term dividends for machine shops.

The following chart illustrates how a 1/2″, 5-flute tool will perform in Steel when varying ADOC and RDOC parameters are used. You can see that by varying the ADOC and RDOC, a higher feed rate is achievable, and thus, a higher MRR. In this case, pairing a high ADOC, low RDOC approach with an increased feed rate was most beneficial. This method has become known as High Efficiency Milling.

Axial Depth of Cut Radial Depth of Cut Feed Rate Material Removal Rate
 .125″  .200″ 19.5 IPM  .488 in.³/min.
.250″ .150″ 26.2 IPM .983 in.³/min.
.500″ .100″ 41.5 IPM 2.08 in.³/min.
.750″ .050″ 89.2 IPM 3.35 in.³/min.
1.00″ .025″ 193 IPM 4.83 in.³/min.

High Efficiency Milling

High Efficiency Milling (HEM) is a milling technique for roughing that utilizes a lower RDOC and a higher ADOC strategy. This spreads wear evenly across the cutting edge, dissipates heat, and reduces the chance of tool failure. This results in a greater ability to increase your MRR, while maintaining and even prolonging tool life versus traditional machining methods.

High Efficiency Milling

The following video provides an excellent look into the efficiency-boosting power of HEM operations. By following the MRR calculation, we can see that @jcast.cnc will have experienced 40.6 cu.in.³ MRR.

MRR = .145″ x .800″ x 350 in./min. = 40.6 in.³/min.

Obviously, with higher MRR’s, chip evacuation becomes vitally important as more chips are evacuated in a shorter period of time. Utilizing a tool best suited for the operation – in terms of quality and flute count – will help to alleviate the additional workload. Additionally, a tool coating optimized for your workpiece material can significantly help with chip packing. Further, compressed air or coolant can help to properly remove chips from the tool and workpiece.

In conclusion, optimizing workplace efficiency is vital to sustained success and continued growth in every business. This is especially true in machine shops, as even a very minor adjustment in operating processes can result in a massive boost in company revenue. Proper machining methods will boost MRR, minimize cycle times, prolong tool life, and maximize shop output.

Zootility – Featured Customer

Zootility prides themselves on designing products that blend art and function for everyday use. Everything from design to manufacturing to distribution is done at their custom shop in Portland, Maine. Utilizing laser-cutters, laser-etchers, and CNC Machines, their skilled team works 15 hours a day to carry out their mission to get their incredibly thin, extremely useful “zootilitarian” tools into pockets everywhere. Zootility was founded by Nate Barr and was launched on the back of a successful Kickstarter campaign for their first tool, the PocketMonkey. Nate has now expanded Zootility and grown into several more products and brands, including the “WildCard” Wallet (Pocket) Knife, “Open Beer Season” bottle openers, the popular “Headgehog” Wallet Comb, and their new line of “Tülry” multi-tools that disguise as fashionable jewelry.

We visited Zootility at their shop in Maine and talked to Nate and Chris, one of their CNC Machinists, about using Kickstarter campaigns to launch new products, the state of the Manufacturing Industry, machining in very tight tolerances, and more in this latest Featured Customer blog.

Thanks for having us, Nate! Tell us a little bit about your shop and how you got started with Zootility.

Nate: Zootility really started as a maker shop for our first product, PocketMonkey. The goal was always to take the idea behind the PocketMonkey and grow it from just a Kickstarter project so that I could expand the business. I also wanted to make sure that I was learning something new myself every step of the way; I wanted to understand how to make our products, so we could keep production in-house and use our knowledge to expand the business in the future. When we started, I was re-investing all of our proceeds back into the business, allowing us to buy more equipment and really build out the shop. Our shop is fairly unique, where we now have nearly total vertical integration across the board. The only thing we need to do now is buy an iron mine and get our own materials!

How did you come up with the idea for the original Pocket Monkey?

Nate: I came up with the idea for the Pocket Monkey one day while I was locked out of my apartment. I was living in Boston at the time, and I would run out every night to the stores around the corner to buy food for dinner, typically only taking my wallet with me. One night, the door locked behind me, and I was locked out, sitting on my front steps and wishing I had some sort of a shim to slip the lock. I started thinking what that would look like and how it could fit in a wallet for easy carrying and realized that I could add on more tools like bottle openers and screwdrivers while still keeping it slim enough to fit in my wallet. I had studied Mechanical Engineering in college, so I had the background to create what I was envisioning.

Pocket Monkey

You have used Kickstarter campaigns very successfully, not only to launch Zootility, but also to further your product line and expand the business. How was the Kickstarter experience, and would you recommend it to other entrepreneurs looking to launch a new business?

Nate: Our Kickstarter experience was great. We have raised up to $90,000 in a single campaign, and we have figured out a strategy that works for us. We found that if you set a reasonable goal that will allow you to cover start-up costs, say $25,000 rather than $100,000, people are more willing to take the time to invest. A reasonable goal gives people more confidence that the project will be funded, and that it will be successful, leading to more backers and more exposure; it is a great Marketing tool in that regard.

Kickstarter also levels the playing field for smaller companies like Zootility – I consider it to be “The Great Equalizer”. There is no longer a need to have tens of thousands of dollars for upfront costs when starting a business. You can spend a little bit of time creating the campaign and invest a small amount of money into that without taking the huge risk of throwing your life savings into an unproven idea. When I started Zootility, I was still working my day job and did not have the money to put up front, so Kickstarter was a natural fit. We have continued to use Kickstarter for new product lines because we are committed to manufacturing our products in the US, so Kickstarter campaigns allow us to validate new ideas and collect funds up front as we continue to grow the business. I do recommend it for all the entrepreneurs out there, and it has been a great tool that has contributed to our success.

You mentioned your commitment to manufacturing Zootility products in the US. What makes this ideal so important to you?

Nate: Let me start by saying that I think that Globalization is a good thing; it has pulled huge numbers of people across the world out of poverty. However, American policies have essentially allowed large corporations to gut the middle class by moving jobs overseas, especially in more rural areas. This has created unbalanced manufacturing and retail sectors. Personally, I believe things have gone too far, and standing behind our belief in American-made goods allows us to contribute to a more balanced approach to manufacturing. As with all things in life, a balanced approach is the best option. There will never be a time when 100% of goods can be feasibly made in America, so overseas manufacturing will continue, but bringing back more jobs to the middle class here in America is a good thing for the entire industry.

zootility

We have definitely made an effort to re-invest in our local community and the people who live here by manufacturing our products right here in Maine. Offshoring has resulted in a loss of knowledge and a real disconnect from the products that we use every day. Products that were previously considered to be of a high quality are now losing their shine, as less care is put into them and there is less appreciation and understanding of how these things are made. By investing in our local community and ourselves by learning something new every day, we believe we are doing our part to bring this knowledge back and instill more of a sense of pride in our employees and the products that they help to create.

You are originally from the Boston area. What made you decide to move the company and shop to Maine?

Nate: I had originally looked at a few places in the Boston-area, but it just didn’t make sense financially. There is a lot of great technology being developed in Boston by the innovative companies in the area, but to set up a manufacturing business in Boston was cost-prohibitive. By moving our shop to Portland, Maine we were able to save a lot on the space, which helped us in the early stages of the business.

The other thing was the lifestyle change. Portland has a great downtown area with lots of small businesses. There are restaurants, breweries, coffee shops, and plenty of locally-owned shops. It is also easy to get around, either by car or bike, and there is very little traffic throughout the city. I also wanted to locate our shop so that it felt like part of a community. We were able to find a great spot in downtown Portland surrounded by other manufacturers and small businesses. It makes for a great place to come to work every day.

What does the future hold for Zootility?

Nate: Right now, we do as much business in Q4 around the holidays as we do the entire rest of the year, so we have been exploring ways to make better use of the machines during the slower months. As we have completed installing and setting up our new machines, we have begun to do contract manufacturing to fill out the rest of the year. We have the unique ability to create small parts with extremely tight tolerances, and we are willing to do small volume, small batch manufacturing that other shops may turn down. We have been getting business from companies in Boston, who are looking for the “just in time” manufacturing which we can provide. The extra revenue from these projects will allow us to take off the Kickstarter training wheels and expand the business faster on our own.

tulry

From a product standpoint, we are looking to launch more “serious” tools for the outdoor enthusiast. Right now we are in the process of launching our new RNGR brand, which will be a line of minimalist every day carry products, without the whimsical nature of the Zootility Tools products. We also are on the verge of shipping our new TÜLRY brand, which is a series of jewelry infused with every day carry tools.

Chris, you create a lot of very thin products. How does that affect your workholding when working in materials that thin?

Chris: Our workholding has been built entirely custom for our CNC machine, due to the nature of the products. For example, we are currently working on our WildCard knives, which are only .040″ thick. There really isn’t much on the workholding market that will work well for something that small, so our team actually machined our own metal strips on the CNC, held the knives down with small bolts, added some rubber bumpers so we do not have metal on metal contact, and it has worked really well for us so far. We also created custom workholding for the new TÜLRY line tools, which are also extremely thin.

helical solutions

The biggest challenge with our custom workholding is the additional time it adds to each job. Right now, we can run batches of 72 knives per cycle, with a cycle time of 28 minutes. Then, we need 20-25 minutes to unscrew each of the bolts, remove the finished knives, and then insert the new knives and screw the bolts back in. However, it is the only way we can machine products this thin with our tight tolerances, and we can still finish around 600 knives per day.

You mentioned your tight tolerances. What are some of the tolerances you are working in every day?

Chris: Right now, all of our tolerances are in the thousandths. For example, the WildCard knives have a tolerance of just +/- .003″, and the screwdriver tools on the TÜLRY necklace, while one of our highest tolerances, stick to just +/- .005″. The tightest tolerance we are currently working in is on the hex wrench tools for the TÜLRY necklace. The hex wrench tools have to be spot on, or they will be too loose when they go to be used on a hex nut. Right now, we like to keep those tools to a tolerance of +/- .001″.

How has your experience been using Harvey and Helical tools on these projects?

Chris: The Harvey and Helical tools have been great for us. When I started, we had another brand of end mills in stock, and they simply weren’t cutting it (no pun intended) in the types of heat-treated stainless steel which we were working in. We switched over to the Helical 7 flute end mills for roughing and finishing of the knives. Each knife has a very small shelf on it, which allows it to be a removable piece of the WildCard tool. We use a 3/8″ 7 flute Helical end mill with a .020″ corner radius for this cut, with a 3/8″ 7 flute square end mill for finishing. One interesting part of this job is that it requires a very low ADOC because the tools are already so thin, that the roughing we do removes only a very small amount of material.

harvey tool

We also use both Harvey and Helical chamfer mills to create all of the box cutter and hex wrench TÜLRY tools. With the hex wrenches, we have found that the 60° tipped off chamfer mill has been great for creating those intricate cuts. With the box cutters, we needed an edge sharp enough to cut through tape and cardboard, but not sharp enough to cut through the skin. We have found that the 2 flute 120° chamfer mills work best for those cuts.

What is the biggest challenge you face at the CNC machine?

Chris: Right now, we laser cut all of the outlines for the knives from a thin sheet of steel. Then the knives come to us right off the laser cutter for machining. The laser cutting does create a rough finish on some of the knives, which can make them hard to lock down when machining. This can result in some movement, which can lead to the occasional scrapped part. The laser cutter can also leave burrs at the start and stop points, or leave a scorch mark or some slag on the knives, which can make them tougher to machine.

The Zootility shop uses a lot of different equipment. How has the CNC machine in particular impacted the shop as a whole?

Chris: Our CNC machine comes in handy for a lot of different things around the shop. As I previously mentioned, we used it to create our own custom workholding, which has worked very well for us. We also used the CNC machine to create all of our forming dies, which are used to create all of our tools from scratch. As we move into more contract manufacturing for other companies, these machines will get even more use when we are working on the small batch jobs we will (hopefully) be getting.

cnc machinist


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What You Need to Know About Coolant for CNC Machining

Coolant in purpose is widely understood – it’s used to temper high temperatures common during machining, and aid in chip evacuation. However, there are several types and styles, each with its own benefits and drawbacks. Knowing which coolant – or if any – is appropriate for your job can help to boost your shop’s profitability, capability, and overall machining performance.

Coolant or Lubricant Purpose

Coolant and lubricant are terms used interchangeably, though not all coolants are lubricants. Compressed air, for example, has no lubricating purpose but works only as a cooling option. Direct coolants – those which make physical contact with a part – can be compressed air, water, oil, synthetics, or semi-synthetics. When directed to the cutting action of a tool, these can help to fend off high temperatures that could lead to melting, warping, discoloration, or tool failure. Additionally, coolant can help evacuate chips from a part, preventing chip recutting and aiding in part finish.

Coolant can be expensive, however, and wasteful if not necessary. Understanding the amount of coolant needed for your job can help your shop’s efficiency.

Types of Coolant Delivery

Coolant is delivered in several different forms – both in properties and pressure. The most common forms include air, mist, flood coolant, high pressure, and Minimum Quantity Lubricant (MQL). Choosing the wrong pressure can lead to part or tool damage, whereas choosing the wrong amount can lead to exhausted shop resources.

Air: Cools and clears chips, but has no lubricity purpose. Air coolant does not cool as efficiently as water or oil-based coolants. For more sensitive materials, air coolant is often preferred over types that come in direct contact with the part. This is true with many plastics, where thermal shock – or rapid expansion and contraction of a part – can occur if direct coolant is applied.

Mist: This type of low pressure coolant is sufficient for instances where chip evacuation and heat are not major concerns. Because the pressure applied is not great in a mist, the part and tool do not undergo additional stresses.

Flood: This low pressure method creates lubricity and flushes chips from a part to avoid chip recutting, a common and tool damaging occurrence.

High Pressure: Similar to flood coolant, but delivered in greater than 1,000 psi. This is a great option for chip removal and evacuation, as it blasts the chips away from the part. While this method will effectively cool a part immediately, the pressure can be high enough to break miniature diameter tooling. This method is used often in deep pocket or drilling operations, and can be delivered via coolant through tooling, or coolant grooves built into the tool itself. Harvey Tool offers Coolant Through Drills and Coolant Through Threadmills.

Minimum Quantity Lubricant (MQL): Every machine shop focuses on how to gain a competitive advantage – to spend less, make more, and boost shop efficiency. That’s why many shops are opting for MQL, along with its obvious environmental benefits. Using only the necessary amount of coolant will dramatically reduce costs and wasted material. This type of lubricant is applied as an aerosol, or an extremely fine mist, to provide just enough coolant to perform a given operation effectively.

To see all of these coolant styles in action, check out the video below from our partners at CimQuest.

In Conclusion

Coolant is all-too-often overlooked as a major component of a machining operation. The type of coolant or lubricant, and the pressure at which it’s applied, is vital to both machining success and optimum shop efficiency. Coolant can be applied as compressed air, mist, in a flooding property, or as high pressure. Certain machines also are MQL able, meaning they can effectively restrict the amount of coolant being applied to the very amount necessary to avoid being wasteful.

Anderson Prototypes – Featured Customer

Anderson Prototypes is a custom machine shop in Port Moody, British Columbia. Working with everything from Titanium to Bamboo, they create mechanical mechanisms and working prototypes of new technology. By applying 25 years of experience with manual and CNC machinery, they craft amazing parts, some even bordering on impossible. The team at Anderson Prototypes works in a variety of industries, ranging from large-scale prototype work to small batch production, machine repair, and even movie and TV props.

Jim Anderson, a 30 year veteran of the manufacturing industry, is the Founder and Owner of Anderson Prototypes. We caught up with Jim and talked to him about some of the “impossible” projects his team likes to take, his experiences in the film industry, and his advice for the aspiring machinist.

Tell us a bit about your shop, how you got started, and what sort of products you manufacture.

I started in machining in 1985, as a full-time student in a machining class at a local community college. I spent years working in jobbing shops, plastic mold injection shops, and specialized start-up companies, scratch building a range of things from high-speed water “pouch” filling machines to hydrogen fuel-cells. Today I work with a wide range of clients including 3 submarine companies, a military contractor, companies that use custom built or modified ROVs and drones, food packaging companies, production companies needing film and TV props, and more.

What made you get into machining?

I have always been an actively creative person, and I enjoyed wood and machine shop in high school. I found a creative outlet for my talents to build and fix things inside the machine shop environment. I continue to study machines and items, to understand how they were made, and how it could be made better or simplified.

anderson prototypes

What is your favorite part of this profession?

I always enjoy creating something for a client that they have been dreaming of, sometimes for years. They come to me with a sketch on a napkin or a verbal idea, and I turn that dream into reality. When they come to pick it up and see it for the first time, the emotions are tremendous!

What sort of machines do you use in your shop?

I have 2 Tormach 1100 CNC mills, one 4 axis and the other 3 axis, a Sherline 2000, 4 axis CNC mill, a Frankenstein CNC lathe with a 8 station tool changer for small work, a Milltronics ML-17 CNC lathe, a Colchester Student Engine Lathe, and a smaller manual milling machine. I also have drill presses, tapping heads and tons of specialized fixturing and work holding devices, as well as a 60 ton hydraulic press and the specialized equipment that comes with it.

micro machining

Which materials do you work with in your shop?

Just about everything. Lots of plastics, PEEK, Delrin and Acrylic, aluminum, steels, stainless steels, carbon fiber, different woods, laminates, and more.

What sets Anderson Prototypes apart from the competition?

We often take on jobs that other shops won’t, due to our team’s large vision. We stand behind every piece we make and have zero returned items to date. Embodying both old-school traditions and cutting-edge technology, Anderson Prototypes believes that “Impossible is just an Opinion”. We work with a project from the very beginning to the time it is up and running at the client’s facility. We work with building very small detailed machines to unique and weird items that someone dreamed up and could not find anyone able to make. We also love to give back to the community. We have sponsored local high school and university students in competitions, and we have played a part in the Maker Community since Day One. We also made and donated a doggy wheelchair to a dog in need (YouTube), and we sponsor a local softball league.

How did you get into the entertainment/prop business?

Vancouver has a huge movie industry, and there are many people in my network that work in the industry. The need for various props, new equipment, and repairs can go up and down as movies are being filmed. The first job I did (I think), was for a movie called Space Buddies, the 4th or 5th entry in the Air Bud movie series. I made the Doggles (dog goggles), that the dog is wearing on the DVD cover. Most movies require a Non-Disclosure Agreements before any work is done, so I can’t talk about much, but I have made my impact on the screen, behind the scenes, and even live on stage. I also did a major prop for an Australian TV show that was apparently popular down under, so you never know where this work will take you!

micro machined

Who is the most famous contact that you have worked on a project with?

I have met many directors and producers of large budget films and TV shows. Unfortunately, because of the Non-Disclosure Agreements, I cannot mention any names.

Why is high-quality tool performance important to you?

I buy all my tooling from North America. I am lucky enough to have a solid carbide tooling manufacturer 5 miles from my shop, so I get quality endmills, made to order. When I need something specialized, Harvey is the only company I go to. When a tool does more than I expect, I make more money and have less stress. I count on that and become a return customer. For example, I used a .018″ Miniature End Mill (#73018-C3) on some acrylic parts I was making. There were 40 parts in total, all around the size of a stamp, with lots of tiny details, high tolerances, and very small features. I had the machine running at 15,500 RPM for 3 weeks, and I only broke one tool in that entire run. What a great tool!

What is your favorite process to work on as a machinist?

I really enjoy making something I have never worked on before, that new challenge. Often it seems that I am designing new items now more than ever. I have to do things that are not being done commercially and I stand behind it. So I might run the manual lathe, the CNC mill and then the CNC lathe on one part. I enjoy the variety.

anderson prototypes

Why is manufacturing your products in North America important to you?

American and Canadian-made products are very important to me. I purchase North American-made products like steel and aluminum, and bearings and fasteners all of kinds. I also access services locally, such as laser cutting, anodizing and powder coating, to support these local businesses. I feel its very important to the customer making the purchase that these are products my neighbors are helping to build.

If you could give one piece of advice to a new machinist ready to take the #PlungeIntoMachining, what would it be?

Take the time to take an accredited machine shop training course, like I did. It will give you all the groundwork to understand the real world of machining. I know a few fellas with small CNCs that can’t make a living because they don’t understand the depth of set-ups or work holding, for example, because they never learned from an expert. They can’t make parts fast enough, they charge 1/2 of what I do, and it takes then 3 times as long, so they simply can’t compete with me. Just be aware that it doesn’t happen overnight; I was a Journeyman Machinist for over 30 years, and still ask for help from my mentors occasionally. Oh, and find yourself a quality machine. Find a good used HAAS, or OKK, or something made in the US, UK or Europe. Your clients will respect you more and it will work longer and more accurately.

Is there anything else you would like to share with the In The Loupe community?

I am grateful for the education I have received from the many journeyman machinists, engineers, mechanics, electricians, pilots, sea captains and more who I have worked beside in my years. I am happy to share and offer problem-solving, sometimes for free, other times at consultation rates. When a young eager person asks me a question, I do the best I can to answer it in a way that benefits them long term. Sometimes they don’t like the answer, but I tell them to come back in 6 months and tell me how it went. That’s when the rubber hits the road.

anderson prototypes


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Photos courtesy of Anderson Prototypes.

Koenig Knives – Featured Customer

Koenig Knives is a fast-growing, Idaho-based knife manufacturer, recognized by many as one of the premier knife-making companies in the market today. Bill Koenig started the company back in 2013, using his off-days  in between his long shifts working the oil fields in North Dakota to build the business. After 3 years of exploring the craft, building a presence in the market, and saving money, Koenig was able to lease a work space, buy his first Haas machine, and start manufacturing his knives right here in America. The Koenig Knives team has now expanded to include four more employees: Krista, the Director of Operations, Cameron, the Lead Machinist, Doug in Assembly, and Todd, who works on finishing. Koenig Knives is quickly becoming known for their focus on quality, innovation, and consistency, backing all of their knives with a lifetime warranty.

We talked with both Bill and Cameron for this latest Featured Customer profile, exploring the world of CNC knifemaking, how they use High Efficiency Milling (HEM) to improve their machining efficiency, and the effect that the machining community on social media has had on their business.

koenig knives

Tell us about your business and how you got started.

Bill: Koenig Knives was started in 2013. I have always been passionate about knives, starting when I was in the Boy Scouts as a young boy. This passion turned to obsession and I went from a collector/enthusiast to a knife manufacturer in December of 2013 when we released our first batch of knives.

Originally we used an off-site manufacturer, who we worked closely with from 2013 until mid-2016. We continued to grow rapidly, and that is when I made the decision to start handling all manufacturing ourselves. We took delivery of our first machine, a Haas VF2SS, at the end of 2016. The rest is history.

What made you get into machining?

Cameron: I started as a CNC operator at an assault rifle manufacturer. After seeing raw material being machined into a beautiful, functioning gun, I decided to make machining my career and I have never looked back.

What sort of machines do you use in your shop?

Cameron: We currently have two Haas VF2SS machines and an Okamoto.

Which materials do you work with in your shop?

Cameron: We work with wide range of materials, including Grade 5 Titanium, Timascus, Damascus, Carbon Fiber, Micarta, Tool Steel , 6061 Aluminum , CTS-XHP, CTS-204P, and 416 Stainless Steel.

helical chamfer mill

What sets Koenig Knives apart from the competition?

Bill: We are often asked what category we would place ourselves in, whether it be production, custom etc. I always hesitate when answering because I can’t think of a way to categorize Koenig Knives besides “high end production with custom offerings.” We have a high end production line, but we also offer the ability to order your own customized version of one of our knives. This is something that is not too common in the industry. Quality, customer service and innovation are our main goals as a company, and we feel we have done a great job hitting on all three.

What is the most challenging part of the knife-making machining process?

Cameron: I think what makes the machining process unique with our product is the fact that we use some of the most cutting edge steel alloys for our blades. It becomes more challenging because these steel alloys are constantly advancing. Finding the perfect harmony of machining parameters for some of the relatively newer steels can be a challenge at times.

Why is high quality tool performance important to you?

Cameron: When part finishes are extremely crucial and there’s a high quantity of parts needed, having high quality tooling like Helical is essential. Helical tools help us maintain a much higher machining efficiency because of the outstanding tool life, while also achieving more aggressive run times. In addition, we are able to consistently keep high tolerances, resulting in a better final product.

koenig knives

What is your favorite process to work on as a machinist?

Cameron: I love everything about this career, except cleaning the coolant tank. I could do without that…

Koenig Knives has a great Instagram following. Tell us more about how the machinist social media community has helped grow your business.

Cameron: The machinist social media community has helped us connect with various knife makers all over the world. We learn from each other by sharing techniques and helpful tips, and we inspire each other by sharing our creations online. The machinist community on Instagram has been great – we would recommend any business, even the smallest job shops, to take a look at starting their own accounts.

Why is manufacturing your products in America important to you?

Bill: Buying American has always been very important to me for many reasons. The sense of supporting fellow American workers was instilled in me at a young age.  When I started Koenig Knives, I wanted to make sure everything from the screws to the boxes was made in the US.

koenig knives

Tell us about your favorite project that Helical helped to create.

Cameron: Machining the Arius blades (pictured above) has been my favorite on-going project. Once we switched to all Helical tools, it drastically improved our run times and blade finish, and created an incredible final product.

Have you used High Efficiency Milling techniques in your shop?

Cameron: Absolutely! We couldn’t do without HEM!

What advice do you have for other machinists who want to try High Efficiency Milling?

Cameron: Machining Advisor Pro is an absolute game changer when it comes to HEM, as well as for general machining solutions. The technical milling strategies and information that Helical makes available give machinists everything they need to be successful. When a machinist has a full understanding of what is taking place and what is needed to efficiently and correctly cut material, the sky is the limit.

If you could give one piece of advice to a new machinist ready to take the #PlungeIntoMachining, what would it be?

Cameron: With machining technology advancing at the amazing rate that it is, there is no better time to become a machinist. It is a trade that is constantly improving, and offers so many opportunities for young people.

koenig knives


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Photos courtesy of Koenig Knives.