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  1. Photo etching: A powerful option for complex precision products

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    Photo etching: A powerful option for complex precision products
    Photo etching enables the creation of complex precision parts while keeping production times and costs low.

    Engineers and designers at OEMs are often tasked with creating startlingly complex parts while keeping costs and time to market down to a minimum.

    For fabricating simple product geometries, photo etching is certainly a smart choice, but the difference between it and other methods may not be as pronounced. However, as these designs become more complex, photo etching’s unique advantages offer substantial benefits in cost and precision.

    Why does photo etching lend itself so well to complex applications?
    Photo etching has proven to be superior to other methods both conventional and nonconventional when it comes to producing complicated products with a high degree of precision.

    In photo etching, the part is machined all at once because the process etches through all unmasked areas of the plate simultaneously. Other methods like CNC punching, laser cutting and wire EDMs work on a small, localized area of the part at one time. These methods take more time than photo etching, are highly vulnerable to undesirable effects like tool wear, uneven locational tolerances and thermal and/or mechanical distortions that lead to deficiencies in the final product.

    OEMs take notice of photo etching’s capabilities
    Dr. David M. Allen, a professor of micro engineering at Cranfield University in England, wrote that photo etching has drawn the eyes of engineers and designers in the microelectronics, mechanical and electrical industries over the last half-century for its ability to provide quick response service for complex precision parts.

    OEMs in these verticals have a high demand for thin gauge (< 2mm in thickness) precision component parts of varying complexity at as low a price point as possible. Allen found that some of the most common examples of this are integrated circuit leadframes, disk drive suspension head assemblies, sieves and meshes, washers, laminations and etched gaskets for use in mobile phones.

    Leadframes – a point of comparison between fabrication methods
    To test specific examples of photo etching’s capacity to deal with complex geometries, the Photo Chemical Machining Institute (PCMI) asked a wide range of companies proficient in different production methods to quote them for parts of various intricacy. Based on the quotes obtained, it was apparent that photo etching was the superior fabrication method as part complexity increased.

    One part for which the PCMI received a quote is a leadframe – a part commonly used in electrical circuits. The organization asked a variety of manufacturers to quote them for a 1 inch leadframe made of nickel iron with a thickness of .008″ and a dimensional tolerance of +/- .001″.

    The only method that found it practical to even attempt to make leadframes was laser cutting. The quoted price for tooling and setup for the laser cutting of 100 parts was 270 percent of the price that photo etching could do for the same part. For bulk purchases, it turned out that the cost of manufacturing 5,000 leadframes was also 270 percent of the cost of etching the same size batch. Batches of 50,000 and above were found to be impractical for laser cutters.

    Other fabrication methods like stamping, wire EDM and water jet cutting fared even worse. These companies couldn’t even quote a price for leadframe manufacture – they all found it to be impractical even in small batches due to the complexity of the part.

    Engineers and designers have many options for simple precision parts. But for the more complex products, the capabilities of photo etching can keep production times and costs low.

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  2. Photo Etching: Superior Non-Conventional Fabricating For Aluminum

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    Photo Etching: Superior Non-Conventional Fabricating For Aluminum
    Aluminum is strong, light­weight and versatile, making it one of the most popular materials for manufacturing components for a wide range of industrial applications. Unfortunately, the same properties that make it so desirable can also make it problematic to work with.

    Aluminum is strong, light­weight and versatile, making it one of the most popular materials for manufacturing components for a wide range of industrial applications. Unfortunately, the same
    properties that make it so desirable can also make it problematic to work with.

    Problems with other nonconventional fabrication methods
    For conventional fabricating processes like stamping and punching, aluminum is just another metal alloy. For the so­-called non­conventional processes like plasma cutting, laser cutting and wire EDM, working with aluminum can be both challenging and hazardous.

    The problem with using the nonconventional methods for fabricating aluminum is exposing the material to high levels of heat. Aluminum’s sensitivity to heat and its reflective surface mean that exposure to high temperatures from plasma, laser or electrical discharge can have a detrimental effect on the final product in terms of material integrity and dimensional accuracy. The Heat Affected Zone (HAZ) forms in metals when the temperature rises above the critical transformation point. Since the HAZ is brittle, this area has a lower tolerance for cracking during bending or stress. In most cases, the HAZ can be eliminated by post-heat treating the part, but there is a risk of distortion. Thermal Distortion is a result of the sudden rise in temperature of the material near the cutting zone. Distortion also can be attributed to the rapid solidification of material remaining on the sides of the cut.

    As if the work wasn’t challenging enough, the hazards involved with heat-intensive fabrication processes such as plasma or laser cutting are not easily avoided. For example, dry cutting aluminum with a plasma beam creates a lot of dust, meaning that insufficient ventilation can lead to high concentrations of harmful particles in the air.

    For these reasons, manufacturers will try to plasma cut materials on a water table. While submerging the work under water removes the hazards associated with dust and heat, it poses other more explosive dangers.

    As ESAB noted, when aluminum metal is submerged in water, it will generate hydrogen gas. To get an idea of how this works, picture a glass of Coca Cola with those tiny carbon dioxide bubbles coming up seemingly out of nowhere to the top of the glass. In the same way, when aluminum is submerged under water, the metal reacts with the water and little bubbles of hydrogen gas rise to the top of the tank. The dangerous part comes in when a high-volume of aluminum parts are made in this way over a period of time.

    Over time, the small aluminum droplets created through the plasma cutting process collect on the bottom of the water table, leaving a large surface area of aluminum that generates hydrogen bubbles over the course of days, weeks and months. If a significant pocket of hydrogen gas gets trapped under the plate and an operator pierces the plate with the plasma beam, it can cause an explosion.

    What makes photo etching superior to other non-conventional processes?
    Since before Conard’s founding, photo etching aluminum was a difficult and inconsistent process. The main problem, even today, is that aluminum has a tendency to oxidize quickly in the etching process, becoming a catalyst for the etching reaction itself. Aluminum can also be etched in both acids and bases meaning that the stripping solution for dissolving the acid-resistant photo resist – itself a base – can also lead to additional unwanted etching.

    So what makes it the superior choice for machining aluminum compared to other nonconventional fabrication methods?

    For starters, it negates the inherent problems of dust creation and high temperatures that come with heat-intensive nonconventional cutting methods. Photo etching is a wet, but not submerged, and cool (125 degrees F) process that creates no thermal stresses and produces no harmful fumes or dust. For this reason, the remaining aluminum’s integrity remains unaltered after the machining process, with no burrs or inconsistent dimensions.

    Even better: Through decades of refining Conard’s proprietary aluminum etching process developed by our founder, Richard Huttinger, we’ve found a way to consistently minimize the impact of aluminum’s natural reaction to the etching and stripping processes, meaning each batch of our aluminum products comes out the same every time. Building on Richard’s foundation, we’ve developed unique proprietary equipment and process metrics that have helped our business expand into many industries that need a low-cost, consistently reliable method for etching high-quality thin gauge aluminum parts.

    If your aluminum needs include:

    • Material thicknesses from .001″ to .080″
    • Dimensional tolerances within +/-15% of material thickness
    • Smooth, consistent edges
    • Design support

    then give us a call at 800-443-5218 or email your designs to us at sales@conardcorp.com and let’s get started photo etching for you!

    Request a Quote

  3. Our Best Selves

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    In the midst of the COVID crisis, thousands of companies and tens of thousands of people stepped up to join in a herculean industrial effort to ramp up production of desperately needed medical equipment and supplies.

    By March 15th,  China had locked down more than 100 million people in Wuhan province and in the US, 3000 cases of COVID-19 had been reported nationally, with more than 80,000 cases worldwide. By March 20th, General Motors and Ventec Life Systems, a manufacturer of ventilators were in talks, with GM’s supply chain team contacting the vendor base of more than 100 suppliers of parts for the life-saving devices. By March 24th, GM was issuing purchase orders for parts for 30,000 ventilators.

    GM repurposed its Kokomo Indiana electronics assembly facility to build ventilators, sending dozens of its own engineers to set up the program. About 1,000 United Auto Workers members signed up to build the machines.

    By late April,  ventilators began shipping from Kokomo. Within a few weeks, the plant was shipping 450 ventilators every day.

    The GM/Ventec team shared this video:

    Along with GM and Ventec, Ford, General Electric, 3M, Siemens and many other companies converted production facilities and ramped up capacity to manufacture masks, gloves, face shields, gowns, respirators and other personal protective gear, as well as more medical equipment. Micro-distillers around the country converted their alcohol production into hand sanitizer.

    At Conard, we are proud to be part of the Ventec supply team and salute the tens of thousands of people and companies that are meeting the challenge as well.

    Across the country, and from within companies large and small, we the people joined together to manufacture  PPE and medical equipment and supplies in a collective effort that rivals the industrial mobilization of World War II. That we do this, in service of the collective good–without expectation of reward or recognition, speaks to our “higher angels.”

    The battle is far from over. At July 9th in our country, more than 3 million cases are recorded, COVID deaths exceed 130,000 and more than 50,000 new cases are  being reported each day.

    Nevertheless, we will persevere. The sheer mass of the efforts underway to develop more effective treatments and ultimately, a vaccine will bear fruit. Until then, all of the companies and people involved in making essential goods to protect first responders and healthcare workers, and equipment and medications to treat the sick will keep up the fight.

  4. OEMs Should Consider Photo Etching For Growing Aluminum Needs

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    OEMs Should Consider Photo Etching For Growing Aluminum Needs
    Demand for aluminum component parts is growing, and photo etching is a superior process for fabricating precision parts.

    Versatile and lightweight, aluminum has been a popular choice for many OEM applications. It can be a struggle to fabricate precision aluminum parts due to certain properties of the metal. As the demand for small-scale, precision aluminum parts increases, OEMs will have to meet their customers’ needs using less conventional ways to manufacture aluminum parts.

    “The aluminum market is projected to grow quickly over the next five years.”

    Aluminum Component Parts In High Demand Across Industries
    Research from investment firm Grace Matthews found that the global market for aluminum is projected to grow at a rate of 5.9 percent over the next five years – a big jump from the roughly 3 percent yearly growth the market saw from 1970 to today. The main reason is that OEMs in clean energy, electronics and telecommunications are looking for ways to reduce product weight and achieve precise tolerances without sacrificing durability. Aluminum components are increasingly effective options.

    This need for lightweight and durable component parts coincides with the trend toward micromanufacturing. Many products are getting lighter and smaller. As part of the expanding Internet of Things, for example, consumer goods are starting to incorporate miniscule microelectronic devices that enable Wi-Fi and RF communication.

    Consumer electronics are just one industry that will require precision aluminum micro parts in greater numbers than ever before.
    Consumer electronics are just one industry that will require precision aluminum micro parts in greater numbers than ever before.

    Photo Etching Has Distinct Advantages In Precision Aluminum Part Fabrication
    At such a small scale, precision is necessary. Conventional fabricating processes may impart undesirable effects, such as burrs and mechanical deformation from stamping and punching and heat affected zones from laser, plasma or wire EDM.

    Even etching can run into problems with aluminum. It’s reactive and oxidizes quickly, becoming a catalyst for the etching reaction. Over the years, we’ve developed equipment and process metrics that help us control the etching process and deliver consistent, high-quality results reliably.

    Etching is a benign process that chemically dissolves unneeded material. There is no cutting or “brute force” and there is no heat-intensive work. The hottest part of the process reaches about 125℉ – about the same temperature as a dishwasher. The aluminum is materially unaffected by the fabrication process and the final parts come out within the specified tolerance.

    Here are some other benefits to working with a photo etcher for your aluminum needs:

    • The process creates no fumes or dust, so it’s safe for workers and machines.
    • No burrs, recast layers or mechanical deformations.
    • Parts are made simultaneously – your costs don’t increase dramatically just because the batch size increases.
    • Design changes are simple and inexpensive. With a new CAD file and $300 or less for new tooling, we can quickly adapt to new designs.
    • For sheets over .005″ thick, minimum dimensional tolerances will be +/- 15% of metal thickness.
    • Aluminum specialists. We’ve devoted decades to honing our aluminum etching processes. Other etching companies come to us for their aluminum needs.

    If you need complex aluminum parts, call us at 800-443-5218 or email your designs to us at sales@conardcorp.com and see how etching can solve your trickiest design problems.

  5. Monthly manufacturing news roundup – November

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    Monthly manufacturing news roundup - November
    Everything from reshoring, to organic job growth, to new STEM training and apprenticeship programs and so much more tell me that American manufacturing is not just surviving, it’s thriving.

    I’ve been hearing a ton of incredible news about manufacturing and technology right here in the United States. Everything from reshoring, to organic job growth, to new STEM training and apprenticeship programs tells me that American manufacturing is not just surviving, it’s thriving.

    In this roundup, I want to highlight some amazing things going on in U.S. manufacturing that are contributing to job growth and exciting innovations.

    American manufacturing’s new Titan
    One cable network is aiming to bring U.S. manufacturing to light a brand new TV show. The Sacramento Bee reported that Titan America MFG, a Grass Valley machine shop owned by Titan Gilroy (and no, that isn’t a nickname), is being featured in on MAVTV, a local cable network in California.

    The show is called “TITAN American Built” and it has one simple message: American manufacturing is unbeatable. Gilroy is using his show as a platform to show that “made in America” isn’t just a cheap slogan – it’s a legitimate business advantage. He wants to grab the attention of business leaders and show them that a strong manufacturing base here in America is to all of our advantages.

    A partnership in Connecticut is investing in the next generation
    An educated workforce is the lifeblood of manufacturing. That means it’s up to the veterans of the industry to pass on their knowledge and skills to the next generation.

    According to Today’s Medical Developments, a joint effort between Tunxis Community College and EDAC Technologies is doing just that in Connecticut. Both organizations are investing in the education of students of all ages who want to start a career in manufacturing. Students will be able to take classes designed in part by EDAC right on Tunxis’ campus. Students who complete the course, which teaches vital machine operating skills, will earn an Advanced Manufacturing Machine Technology Certificate. The program’s organizers said that the program will address ensure the growing number of manufacturing positions are filled with skilled workers.

    Manufacturing wages on the rise
    Looking at the recent manufacturing job wage increases in many regions of the U.S., we might need more training programs to deal with all of the people looking to get in on these lucrative jobs. The Wall Street Journal reported that manufacturing wages have risen considerably, making manufacturing an even more attractive career choice for new workers.

    Even though the bulk of the high wage growth has been seen in just a few regions now, the Wall Street Journal expects the rest of the country to start catching up. In states like Connecticut, with new programs offering people a way into these new high-paying jobs, growth could come sooner rather than later.

    Make sure you tune in next month as we continue our roundup of good news in U.S. manufacturing!

  6. It’s a Good Time to be an American Manufacturer

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    15.6 million vehicles were sold in the US in 2013; the best year for the auto industry since 2007. The 2014 forecast calls for 16 million vehicles, more than half of which will be manufactured in North America.

    Boeing has an order backlog of more than 4800 commercial aircraft worth more than $345 billion. The industry forecast calls for nearly 30,000 new commercial aircraft over the next 20 years.

    These two demand streams are a big part of the “rising tide that floats all boats.”  More than 400,000 US manufacturing organizations produce the myriads of components that are needed for vehicles, aircraft and many more types of industrial, commercial and consumer products.

    Manufacturing activities employ more than 13 million Americans directly. Each manufacturing position supports 1.7 indirect jobs, accounting for another 22 million people employed.

    The Manufacturers’ Alliance for Productivity and Innovation (MAPI) forecasts a 3% increase in industrial output for 2014.

    “Re-shoring” is bringing manufacturing back to the US, and the data is accumulating. The Reshoring Initiative has been tracking manufacturers’ return to domestic production facilities and recently estimated that 50,000 US jobs have been re-created and 30,000 new manufacturing jobs have been created in the last three years.

    “Made in America” is becoming more than a preference for many buyers.

    Advances in technology, automation and quality enable American manufacturers to be among the most cost effective and productive in the world.

    And we’re proud to be part  of that.

  7. In-flight Wi-Fi takes off – can photo etching play a role?

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    In-flight Wi-Fi takes off - can photo etching play a role?
    After several years of stalled growth, in-flight Wi-Fi appears slated for widespread adoption.

    After several years of stalled growth, in-flight Wi-Fi appears slated for widespread adoption. An article from the Washington Post explained that as more consumers come to expect wireless Internet connections wherever they go and airlines are responding by outfitting their airplanes with upgraded communications technologies that will allow for faster Internet and even video and music streaming.

    These new communications systems will make use of the 3GHz spectrum (which beams 3G signals from towers), Ku antennas and satellite technologies to provide the Wi-Fi capabilities on board each plane. As this communications infrastructure on the ground and in space is further developed, we can expect to see more aerospace and RF & Microwave manufacturers working to build Internet connectivity right into planes.

    OEMs in these industries should consider photo etching for the component parts they will need for this fast-emerging product category. Here are a few advantages photo etching offer the communications sector:

    A variety of metals
    Copper and copper alloys, like brass and beryllium copper, are frequently used in the etching process. RF & Microwave manufacturers prefer these materials due to their current- and signal-carrying capabilities. Additionally, aluminum is a common component in antenna manufacturing.

    In some rare cases, carbon or galvanized steel is used for these purposes, and those can also be etched. A good photo etching shop will also be able to electroplate the surfaces of your parts with metals such as nickel under silver, gold or palladium.

    The demand for communications and Wi-Fi technology on airplanes is poised to grow. OEMs should be sure to work with supply chain partners that can help them create the products they need.
    The demand for communications and Wi-Fi technology on airplanes is poised to grow. OEMs should be sure to work with supply chain partners that can help them create the products they need.

    The ability to handle complex designs
    For OEMs that create communications and Wi-Fi-enhanced products, the ability to create complex component part geometries out of thin gauge metals is essential. Photo etching is well-suited to this kind of work because the parts are machined all at once, with all unmasked areas of the sheet being etched simultaneously. The etching process leaves no burrs and ensures that all tolerances are held to within +/- 15% of the part’s thickness.

    Other methods like punching, laser cutting and wire EDMs only work on a small, localized area of the part at one time. These methods take more time than photo etching, are vulnerable to undesirable side effects like tool wear, uneven locational tolerances and thermal and/or mechanical distortions that lead to deficiencies in the final product. This is essential for communications technology for aerospace applications, which is expected to be compact, lightweight and precise.

    High production volumes are no problem
    Photo etching uses phototools to create parts in volumes ranging from dozens to hundreds of thousands. A phototool is a stencil of the finished part printed on dimensionally stable mylar using an 8,000-dpi photoplotter. The phototool gets laminated to both sides of the sheet metal, and the etching solution dissolves the exposed metal in the shape of the final part. Most tools cost $300 or less, and since there is no “hard tooling,” we can create as many as you need without substantially driving your costs up.

    To find out if photo etching works for your application:

    Request A Quote

    To learn more about how your OEM can benefit from working with a photo etcher, call us at 800-443-5218 or email us at sales@conardcorp.com.

  8. Industrial Applications of Photo Etching Across Sectors

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    Discover the transformative power of photo etching, a versatile and precise manufacturing process revolutionizing various industries.

    The Fundamentals of Photo Etching

    Photo etching, also known as chemical etching and photo chemical machining, is a subtractive manufacturing process that uses chemical solutions to remove material from a metal surface. This technique is highly precise and can create intricate and complex designs that are difficult to achieve with traditional machining methods.

    To people familiar with printed circuit board fabrication, photo etching  uses many of the same process steps: laminating, imaging and developing the photoresist, etching the metal and removing the resist. The key difference is that there is no non-conductive component such as Kapton for flex circuits or FR4 for rigid boards supporting the metal.

    Designing for Photo Chemical Machining

    Most of the “heavy lifting ” in design these days is done by any of the solid modeling systems now in wide use. Most modern systems have design rules for different fabricating processes “baked into”  the systems’ architecture.

    Unfortunately, none of them recognize photo chemical machining as a production option. So how can an engineer or designer compare whether stamping, laser cutting or photo etching would be the most effective and economical choice for manufacturing?

    Rules for Efficiency and Economy

    Choose An Alloy that’s Available

    The first step is to assess the application and try to select the most readily available types of metal alloys. All to often, we see projects where the specifier didn’t take the time to research whether the selected alloy is actually available. Global events like the Covid pandemic and the “Great Recession” of 2008, roiled many industries, including the metal mills. As existing inventories were exhausted, the mills become much more selective about what they would manufacture. The “cornucopia” approach of make everything and eventually we’ll sell it was replaced by only make what sells best. The mills aren’t going to roll 50,000 pounds of something that is going to take 20 years to sell through any more.

    Choose the Lightest Gauge that Satisfies the Application

    It seems there may be a universal compulsion to enhance: if “A” is good, then “A-plus” must be better. Acquiescing to this compulsion in design for etching has three  meaningful consequences:

    • the metal weighs and therefore costs more ,
    • the etching time -the most expensive time in the shop- increases in a linear fashion with the metal thickness, and
    • the minimum dimensional tolerances, which are a function of metal thickness, range higher

    Choose the Most Generous Tolerances Possible

    While metal thickness defines what the minimum tolerances can be, more generous tolerances enable using largest possible sheet sizes for the best economy.

    Diverse Industrial Applications of Photo Etching

    Photo etching is employed across a broad range of industries due to its versatility and precision. In the electronics industry, it is used to manufacture components such as lead frames, RF shields, and connectors. The medical industry utilizes photo etching to produce surgical instruments, implantable devices, and microfluidic channels.

    Metal filtration and other perforated products, including screens, masks, and grids and the like, are excellent candidates for photo etching. As are seals, gaskets, shims and other metal-to-metal applications.

    In the aerospace and automotive sectors, photo etching is used to create intricate parts like fuel injector nozzles, filters, and heat exchangers. A significant move to using etched braze foil pre-forms has found many new applications in aerospace niches.

    Fuels cells and batteries for mobile applications, including aircraft!, is a burgeoning area of growth for photo etching.

    The process is also valuable in the production of decorative items, such as jewelry and nameplates, thanks to its ability to produce fine details and complex patterns.

    Future Trends in Photo Etching Technology

    The future of photo etching technology is promising, with ongoing advancements aimed at enhancing precision, efficiency, and environmental sustainability. Innovations in photomask technology and photoresist materials are enabling higher resolution and more intricate designs.

    Additionally, the development of eco-friendly etching solutions and waste treatment methods is addressing environmental concerns associated with chemical etching. As industries continue to demand smaller, more complex components, photo etching technology is poised to play a pivotal role in meeting these evolving needs.

    Download the Guide

    Get the Comprehensive Guide Here

  9. Industrial Applications for Photo Etching

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    Photo etching is the process of choice for fabricating metal components used in an impressive range of industrial applications, both mechanical and electrical/electronic.

    Industrial Applications for Photo Etching

    Manufacturers of scientific and medical instruments, such as blood and gas analyzers, spectrometers, seismographic devices, metrology instruments, MRI equipment and many more utilize photo etched parts. For power generation/storage devices, including turbines, fuel cells and batteries, chemical machining is the only practical process for manufacturing parts with complex structures.

    Even simple parts, like shims and spacers, can be readily and economically produced in a range of materials and thicknesses. Etching is also convenient for flat springs, shields and retainers.

    Find more detail about mechanical applications here.

    Industrial Applications for Photo Etching

    Filtration, from finely detailed deposition masks to robust separation screens in food processing, is another application where metal etching has some meaningful advantages because the incremental cost of holes is “zero.” Whether it’s one hole or a million, there is no additional cost in the tooling; there is no additional time in manufacturing and no additional cost at all.

    On the electronics side, photo etching is the darling of wireless communications. From the handsets to the towers, the “un-wired” world benefits from the ease of fabricating unusual geometries, quickly and cost effectively. And, even at the chip level, high density leadframes can be coaxed into being using high resolution phototools.

    Industrial Applications for Photo Etching

    Copper alloys, including beryllium copper and phosphor bronze, are readily etched and have great utility in making resilient electrical contacts. Nickel alloys figure prominently in electronic packaging, particularly with regard to the “controlled expansion” classes of nickel-iron (Invar, Alloy 42 etc) and nickel-iron-cobalt (Kovar).

    The popular construction for power electronics circuits is direct bond copper (DBC) on alumina or aluminum nitride. The big factor in these devices is shedding heat, which is the main purpose of the ceramic substrates. Photo etching is the only practical fabrication process.

    Flexible resistive heating elements and flex circuits are also in the set of electrical applications.

    For additional information about design and applications for photo chemical machining:

    Design Considerations
    for Photo Etching

  10. I mostly call it Photo Etching

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    How many names does it need?

    As the Sales & Marketing person here at Conard, the three biggest problems I fight every day about what we do are these:

    1. The photo chemical machining process is not well known in the metal fabricating world and not at all in the knowledge base of solid modeling software;
    2. For the engineers and designers that could benefit from it, there is precious little information about etching in the wild; and
    3. The process has too many names!

    It’s like a major case of multiple identity disorder: photo chemical machining, PCM, photo chemical etching, photo etching, chemical etching and chemical machining all refer to the same process

    As if that’s not enough, there are three additional, similar sounding processes that are NOT photo etching. 

    • Electro chemical etching (sometimes called electrolytic etching) is a process used for part marking on metal parts.
    • The MetalPhoto process utilizes pre-treated aluminum panels to create nameplates and identification products.
    • Chemical milling is a process used to modify parts by selectively removing metal from specific areas. Chemical milling is often used on airframe components to reduce weight.

    Photo chemical etching is not subject to Nadcap because the etching process does not alter the properties of the material.

    [Chemical milling may be subject to Nadcap checklist 7108/5. Nadcap (formerly NADCAP, the National Aerospace and Defense Contractors Accreditation Program) is a global cooperative accreditation program for aerospace engineering, defense, and related industries. Nadcap covers a range of special processes with uniform standards. ]

    Finding a cup of coffee or a burger: easy. Finding an etching supplier: *crickets*.

    Photochemical machining is a relatively rare process. There are only about 100 PCM shops in the country and barely a few hundred globally. Compare that to about 2,000 metal stamping shops, just in the US. Photochemical etching is often a better solution to fabricating flat metal parts, but too few people are familiar with the process.

    Etching is cleaner than people realize.

    We also must overcome misperceptions about etching and the environment. Today, all-aqueous chemistries are used. PCM is closely monitored by environmental protection departments in every state where there are PCM shops. We take environmental responsibility very seriously. We have state of the art water treatment facilities. Our process waste water is cleaner than the municipal water supply. We must “clean” the city water in a de-ionizing column before we can use it in the etching process.

    It’s surprising how often we receive inquiries from people who “want to buy a photo etching machine.”  It’s not a photocopier.

    Photo etching is a process that involves a considerable suite of specialized facilities and equipment. There are six operations performed by dedicated capital equipment. Our facility has a 5000-gallon spill-containment sump. We discharge an average of 4000 gallons of treated process water every day.

    Photo etching is a metal fabricating process that fits in a spectrum that includes metal stamping, CNC punching, laser, plasma and water-jet cutting, and wire EDM. 

    The result of all these processes is flat metal parts. Stamping and punching are processes that require hard metal tooling to cut parts from sheets of metal. Laser, plasma and water jet use narrow beams of focused energy. In the case of the laser, the energy comes from collimated light, and the water jet uses a pressurized abrasive slurry. Plasma uses a beam of highly energized gas. Wire EDM uses a wire electrode to burn the parts out of metal.

    Stamping and punching create mechanical stresses and burrs on the metal. Laser, plasma and EDM generate thermal stresses which may alter the characteristics of the metal.

    Among the advantages of etching is that etched parts do not acquire any thermal or mechanical stresses during fabrication. The unwanted metal is dissolved by the etchant and rinsed away. We think of it as “stress free machining.”

    Thousands of companies in dozens of industries rely on etched metal components.