In this fast-paced market, where consumers crave both luxury and sustainability, staying ahead of the curve is crucial. This article delves into the key trends transforming the industry, from captivating design elements to eco-conscious solutions, empowering you to create packaging that not only looks good but resonates with today’s savvy consumers. 

Product differentiation drives sales 

In an increasingly crowded marketplace, creating a unique style for cosmetic packaging is key to catching the eye of consumers and building brand loyalty. Consumers look for details in the design, such as embossed logos on caps, custom colors, unique materials like copper and aluminum, and exclusive shapes (Figure 1). 

Figure 1. Distinctive shapes and mixed materials help products stand out in the beauty market.  

Consumers also expect a luxe feel when purchasing a beauty product with a high price point. Using substantial materials in packaging gives even miniature products a high-end feel.  

Additive manufacturing supports new product development  

Developing products with novel designs requires expertise and options for scaling if products become popular. Since the cosmetics industry moves quickly, bringing a new product from conception to design to reveal is essential for its relevance. And because customer preferences can pivot rapidly, manufacturing a limited number of new products using cost-effective techniques to test the market is also important.  

Additive manufacturing processes like 3D printing meet both requirements—they can produce parts quickly and don’t require huge upfront costs (Figure 2). 

Figure 2. Carbon® Digital Light Synthesis™ is one of SyBridge’s many 3D printing techniques 

Companies can scale production with high cavitation injection molds or other production techniques if the product is commercially viable. Although specialty tooling capabilities may have a higher upfront cost, their ability to support higher production runs and longer lifetime cycles ensures they remain cost-effective. The ability to start small and scale ultimately results in the lowest overall cost of ownership for brand owners.  

Using sustainable materials and designs to appeal to consumers  

Sustainability continues to be a trend for consumer products in 2024, including cosmetic packaging. However, most consumers are unwilling to compromise on increased prices for more sustainable products. Manufacturers must find a way to produce sustainable packaging that is also cost-effective.  

Toward more sustainable cosmetic packaging  

Refillable and reusable packaging is emerging as a more environmentally friendly alternative to single-use packaging. Other sustainability trends include using either post-consumer recycled (PCR) plastic or aluminum for manufacturing or creating products made of single, recyclable plastics (mono-material) instead of a mixture of plastic and metal (Figure 3).  

Figure 3. Material selection simplifies sustainability for consumers 

Mono-material packaging simplifies recycling but does come with challenges, such as finding plastic alternatives to metal springs and other traditional metal components. Manufacturers are also limited in design by choosing mono-material packaging because they can’t use decorative metal coatings.  

A simple way to meet the demand for sustainable packaging without making consumers pay more for beauty products is by choosing a minimalist design (Figure 4). Sleek designs without added decorative features can reduce production complexity and material usage. The challenge to choosing minimalist designs is standing out in a market that relies so much on eye-catching products.  

Figure 4. Minimalist designs can reduce material usage and simplify production  

Design services help meet manufacturing challenges  

Producing flawless cosmetic packaging with the luxe feel consumers expect using sustainable materials is a serious challenge. That’s where working with companies with design services and a range of manufacturing capabilities becomes essential. SyBridge experts can complete design for manufacturability (DFM) checks and simulation analysis to identify production issues before production begins, reducing design iterations and saving on production costs (Figure 4). 

Figure 5. DFM checks help determine how to manufacture the highest-quality part at the lowest possible cost per unit. 

Design services are essential not only for testing novel ideas but also for optimizing current production. SyBridge experts can use product data and analytic tools to create a digital thread — a centralized source of truth for the part. We use the digital thread to gain insights about a part’s lifecycle (design to final production) and see opportunities for increased efficiency and improved quality (Figure 5).  

Novel dispensing methods make for more hygienic products  

A carryover from the COVID-19 pandemic continuing to influence health and beauty products is an emphasis on hygiene. Where many skincare and makeup products require brushes or even a fingertip for application, consumers are now choosing contactless options like droppers, misters, products with internal applicators, and airless pumps.  

Airless pumps reduce the chance of harmful bacteria getting into beauty products during use or illnesses spreading between people sharing the product (Figure 6). Pump dispensers also give customers precise control over how much product they use because each pump produces an exact volume. Companies can use pumps as an opportunity to provide instant brand recognition through contoured pump heads and other unique details.  

Figure 6. Airless pumps help reduce the spread of microbes and regulate dosing. 

In addition to enhanced hygiene and dosing control, the airless packaging used in pumps and sprays can preserve the chemical composition of the formula by not introducing oxygen during use. This extends the product’s shelf life. Airless packaging can help reduce waste, and it is often made from mono-material, making it 100% recyclable.  

Manufacturing for optimal user experience and safe shipping 

A challenge for manufacturing novel dispensing methods is ensuring function. Consumers can easily become frustrated and dissatisfied when features such as pumps malfunction, ultimately costing brands the loyalty they have worked hard to gain. Precise manufacturing is essential to avoid warpages, stress cracks, and other flaws that can cause packaging to malfunction. 

E-commerce companies selling cosmetics also need packaging that meets shipping standards. Products must have the strength to withstand rough handling during transportation, sortation, and distribution.  

SyBridge helps companies manufacture uniform, strong products by incorporating quality inspection services and advanced designs, such as conformal cooling, in our manufacturing technology. Our precision manufacturing can help companies achieve high-feature, aesthetic parts that are also functional. 

Partnering with SyBridge  

Manufacturing partnerships help cosmetics companies maintain a competitive edge in the fast-paced industry. Since needs vary by product, partners with multiple capabilities are especially valuable and critical to support reduced overall tooling costs. SyBridge experts can help cosmetics packaging manufacturers wherever they are—whether seeing if a novel design is achievable or choosing the best manufacturing technology for a proven product.  

Staying ahead of 2024 beauty trends is possible with the right partners. Connect with a SyBridge expert today to learn how our comprehensive services can help you meet your goals this year.  

The post 2024 Trends in Cosmetic Packaging appeared first on SyBridge Technologies.

The urethane casting build process involves first creating a master pattern — essentially a replica (often 3D printed) of the final part. The pattern is then fully encased in liquid silicone and allowed to cure. The mold is cut into halves and the pattern removed. From there, the process can be repeated using the proper urethane casting resin.

Polyurethane casting materials are capable of providing performance characteristics comparable — if not superior — to the thermoplastics used in injection molding. However, as with other production methods, the process of casting high-quality parts that meet all performance requirements also requires that product teams follow design for manufacturability (DFM) best practices. Here are some of the most important guidelines for product teams to keep in mind:

Tolerances

Some degree of variation is inevitable in manufacturing (though teams should endeavor to account for as many of the variables as possible), and tolerances are the acceptable amount of dimensional variation between individual units. Cast urethane tolerances are typically around  ± 0.015” or ± 0.003 per inch, whichever is greater. Tighter tolerances may be offered on a case-by-case basis.

In general, a shrinkage rate of +0.15% is typical. This is caused by the thermal expansion of the urethane casting material and how the flexible silicone mold warms in response.

Additionally, it’s important to note that while urethane cast parts take well to post-processing (though additional processes, such as polishing or custom finishing, can quickly drive up production costs), some design features like sharp corners or lettering may experience slight rounding in the cooling process, impacting the definition of finer details. That said, it is possible to add a finish to the master pattern that mimics an SPI finish or texture. You can also paint urethane cast parts to match Pantone colors, and certain color and pigments can be added directly to the casting materials, as well.

Wall Thickness

Parts produced with urethane casting should have a minimum wall thickness of 0.040” (1mm), though walls as thin as 0.020” (0.5mm) can be achieved for some small components. Larger parts generally require thicker walls in order to ensure the piece’s structural integrity.

Urethane casting does allow for parts with varying wall thicknesses or irregular geometries, but designing parts as such should be done only when strictly necessary. Maintaining a consistent thickness helps to minimize the potential for improper shrinkage and deformation during the curing process.

Undercuts and Draft

While undercuts can quickly complicate injection molding design, the flexible nature of the silicone molds used in urethane casting typically allows for parts to be removed easily and without damage.

The same is true for draft angles: they are a necessity for ejecting pieces from metal molds, but less essential for urethane-cast parts. That said, incorporating 3-5 degrees of draft into part design can significantly reduce strain on your mold and extend its life cycle.

Ribs

Ribs add stability and strength, but it’s important to ensure that they are oriented so as to maximize the bending stiffness of the walls they support. As a general rule of thumb, the rib’s height should be no more than three times its width, and the width of the rib where it meets the part wall should be between 40-60% of the wall thickness. Lastly, to maximize the strength of the rib, all interior corners should have a fillet radius of at least 25% of the part’s wall thickness.

Bosses

Bosses allow secure mating parts to be attached through the use of screws, pins, and other fasteners. As with ribs, the base radius should be about 25% of the part’s wall thickness, which has the added benefit in this case of helping to prevent the fastener from burning when it’s set into the boss.

Interior boss corners should use a 0.060” (1.5mm) fillet radius to minimize thickness and reduce the likelihood of sinks developing. Ensuring that bosses are no more than 60% of the nominal wall thickness also helps to minimize shrinkage.

Leverage the Benefits of Urethane Casting Today

The advantages of urethane casting — short lead times, low cost, and design and material flexibility, to name a few — only truly pay off if you adhere to design and manufacturing best practices. This means paying attention to variables like urethane casting material properties, general tolerances for rubber parts, and everything in between — which quickly becomes complicated without the assistance of an experienced manufacturing partner.

With our agile approach, we’re able to significantly shorten lead times and increase operational efficiency for product teams of all shapes and sizes. And at SyBridge, our business isn’t just based on manufacturing superior parts — we also work tirelessly to make sure that our production processes are as efficient as possible, even if that means using a combination of techniques to get the job done. Contact us today to learn more.

The post Critical Design Guidelines for Urethane Casting appeared first on SyBridge Technologies.

In this downloadable guide, we’ve compiled eight common DFM considerations that should remain top-of-mind when designing parts for CNC machining. You can save significant time and cost by checking your design against this list before submitting it for manufacturing.

Top 8 Design for Manufacturing Considerations for CNC Machining

1. Are there any deep pockets in the design?

Deep-narrow pockets or slots must be machined by longer tools, and longer tools are more prone to breakage, and can also cause chatter, or machine vibrations. Additionally, it takes several passes to machine a deep pocket, which drives up machining time and manufacturing costs.

Avoid designing parts with deep pockets whenever possible. If a deep pocket cannot be avoided, engineers and designers should decrease its depth as much as possible or increase the cross-section area of the pocket. As a rule, pocket depth shouldn’t exceed 3x the diameter of the tool being used to make it. For example, pockets should be no deeper than 1.5” when using a 0.5” cutter.  Engineers may have to adjust this figure based on the material they are using and the tools that are available to them.

2. Are there any narrow regions?

Narrow regions are difficult to manufacture because the size of the cutter is restricted by the smallest distance between the various faces of the feature. Long and small diameter cutters are prone to breakage and chatter.

Avoid designing features or faces that are too narrow for a cutter to easily pass through. If narrow regions cannot be avoided, however, they must not be too deep. Remember that the depth of any feature should be less than 3x the diameter of the tool.  As a best practice, wall sections should be greater than 0.01 inches thick. A shorter cutter with a larger diameter can also be employed to reduce chatter.

3. Are there any sharp internal corners?

Since all CNC drill bits are circular, it’s difficult to achieve sharp internal corners. Instead, the drill bit will leave behind a pocket of unmachined space called an internal corner radius. It’s possible to machine sharp internal corners using workarounds, like electrical discharge machining, but these methods tend to be expensive.

Avoid sharp inside corners whenever possible. Ideally, a corner radius needs to be slightly larger than the cutter. If a corner radius is the same diameter as the cutter being used to form it, it can cause chatter and premature tool wear.

Increasing the corner radii beyond the standard value by as little as 0.005” can give the tool enough room to move around and follow a more circular path.

4. Are there any inaccessible features?

Inaccessible features like counterbores that open inside another pocket or pockets with negative drafts take longer to machine— if they’re even possible — because the cutting tool cannot easily access them, which in turn drives up costs.

You should ensure a cutting tool has full access to all features within a part without being blocked by another feature.

5. Are there any outside fillets?

Outside fillets, or fillets on the top edges of pockets, bosses, and slots, require an exceptionally sharp cutter and a precise setup. Both of these requirements can be prohibitively expensive for some product teams. To avoid incurring these costs, bevel or chamfer — rather than fillet — the outside edges of features.

6. Are the part’s walls too thin?

When it comes to CNC machining with metal, thin walls increase chatter, which can compromise the accuracy of the machining process and the surface finish of the part. With plastics, thin walls can cause warping and softening. As such, you should do your best to avoid designing parts with thin walls.

The ideal minimum wall thickness for metals is 0.8 mm for metals and 1.5 mm for plastics. You may be able to achieve thinner sections without significant risk, but this needs to be assessed on a case by case basis.

7. Are there any flat-bottomed holes?

Flat-bottomed holes require advanced machining operations and often cause problems down the line for subsequent operations like reaming. Avoid creating blind holes with a flat bottom — especially small holes — and instead use a standard twist drill to create holes with cone-shaped bottoms. Cone angles are commonly 118° or 135°.

8. Can the CNC machine’s drills enter and exit easily?

A drill tip will wander when it comes into contact with the material’s surface if that surface isn’t perpendicular to the drill axis. Also, uneven exit burrs around the exit hole will make removing the burr difficult. To ease entry and exit, avoid designing hole features with start and end faces that are not perpendicular to the drill’s axis.

Recap of All 8 Design Considerations for CNC Machining

1. Avoid designing parts with deep pockets whenever possible because deep-narrow pockets can drive up machining time and cost.
2. Avoid designing features or faces that are too narrow for a cutter to easily pass through to prevent tool breakage and chatter.
3. Radiused corners (middle) or “dog bones” (right) are good alternatives to sharp internal corners.
4. Ensure a cutting tool has full access to all features within a part without being blocked by another feature
5. Avoid outside fillets (shown left) and opt for chamfered edges (right) to save time and cost.
6. Avoid designing thin walls, as they’ll increase chatter in metals and cause warping or softening in plastics.
7. Avoid Flat-bottomed holes that can cause problems for subsequent operations like reaming.
8. Whenever possible, design hole features with start and end faces perpendicular to the drill’s access.

Get Started With a DFM Expert

Designing for manufacturability accelerates the CNC machining process, reduces operating costs, elevates energy efficiency, and helps product teams create clean, functional parts. Refer to this short checklist often to make sure your designs are on the right track, but an experienced manufacturing partner like SyBridge can offer more nuanced insights.

The SyBridge team can help engineers, designers, and product teams ensure they don’t miss the mark when it comes to DFM. We have access to the latest digital design technologies available so our partners can take their designs to the next level, while we provide expert advice on manufacturability and part quality. What’s more, our experts are prepared to assist customers with design and prototyping for a range of manufacturing methods — from CNC machining and injection molding to urethane casting and 3D printing. Let’s create something incredible. Contact us today.

The post The Ultimate CNC Design for Manufacturability (DFM) Checklist appeared first on SyBridge Technologies.

by Charlie Wood, Ph.D.
VP of Innovation, Research & Development

As a part of the SyBridge team, I’ve witnessed the remarkable evolution of design and engineering tools over the past decade. These digital advancements have revolutionized our approach to manufacturing, allowing for more data-driven processes and insights. But it can be difficult to know where to start, or even to understand where there are opportunities to implement.

At the heart of our approach lies the concept of the “Digital Thread,” a framework that interconnects data across the entire lifecycle. This concept enables us to leverage the wealth of design and operational data across our data lake that is generated in the manufacturing process, from CAD designs to inspection results. While the industry is still moving towards seamless integration, we’ve made significant strides in creating workflows that prioritize data-driven decision-making.

Streamlining Injection Mold Design Workflows

One key area where data is contributing to efficiencies within manufacturing is that of injection mold tooling design. By utilizing virtual component libraries for mold designs, we’ve been able to streamline the complex process of coordinating and collaborating on intricate assemblies for mold making. In these libraries, we have standard blocks, system approaches and components stored in a way that allows us to quickly identify and digitally pull components. This approach offers lots of flexibility when it comes to customer requests and needs, all while keeping standard practices built right into our tools. Over the course of many years, we’ve built software-driven processes to design new builds based off of these standard components, allowing us to quickly handle new requests from customers and build a learning feedback loop to avoid costly mistakes.

Additionally, through the use of parametric component libraries, we’ve been able to significantly reduce design complexity and incorporate our own manufacturing intelligence into these components, allowing us to directly check for design issues and integrate manufacturing information into CAD files. This process creates a flow of information from the conceptual stage of the design through manufacturing and approval, extending our Digital Thread from end to end. This information flow can also go backwards, tying quoting, estimation assumptions and specifications directly to tool designs. These advancements in our design approach have not only made the job of a tool designer a bit easier, but have improved quality by creating
more explicit feedback loops in our design processes.

Innovations in Conformal Cooling

As many know, 3D printing has unlocked incredible design freedom for manufacturing engineers around the world. However, what can be overlooked is how impactful it has been for system designers, like toolmakers, who can utilize that design freedom and low cost of complexity to create components that radically improve performance. In the case of toolmaking, 3D printing has unlocked new cooling channel designs simply not possible before.

Although increasing numbers of toolmakers are using these advanced manufacturing techniques today, the new design space is so complex it can be hard to probe. In the past, conformal cooling channels were fairly straight, in-plane paths driven by tool access limitations in machining. With metal 3D printing, the limits are far less restrictive and allow designers to pursue more creative and complicated structures.

Using advanced data-driven methods with virtual design and testing capabilities, we’ve been able to uncover non-obvious opportunity areas in the design space. Through these novel design and
manufacturing workflows, we’re optimizing cooling performance and achieving remarkable improvements in tool performance as measured through cycle time. Through our approach, we’re seeing cycle time reductions as high as 50%. These successes have inspired us to further integrate and enhance these workflows, driving continued innovation.

AI Tools for Manufacturing

The Fast Radius Portal’s AI-powered DFM checks

Looking ahead, we’re enthusiastic about the possibilities that emerging technologies like machine learning (ML) and artificial intelligence (AI) offer. These novel data modeling approaches have shown incredible potential, and the pace of technological advancement is rapidly accelerating. We’ve been able to use ML models to build data models faster than through simple bottom-up logic, particularly for complex problems that contain many correlating factors.

The critical ingredient in implementing AI for manufacturing are large data sets that provide a source of truth for model training and validation. By leveraging our existing datasets, we aim to predict defects, optimize designs in real-time and ultimately revolutionize quality control processes. These technologies are not a distant vision; they’re an integral part of our current digital platform, with features like instant quoting and DFM checks based on captured manufacturing data. And this is just the beginning of what’s possible.

Unlocking Manufacturing Innovation via the Digital Thread

Our journey in harnessing digital workflows for injection molding design has seen remarkable progress and tangible results. The end-to-end integration of data into the Digital Thread, combined with the power of ML and AI, holds the key to unlocking even greater innovation. As we continue to push boundaries and explore new frontiers, we’re excited about the advancements at the interface between the physical and digital worlds.

Are you ready to harness the power of the Digital Thread for your organization? Contact us today to get started.

The post The Digital Thread: End-to-End Data-Driven Manufacturing appeared first on SyBridge Technologies.

Reduced Risk of Part Warpage

During the molding process a part cools from the exterior surface to the inner core of the plastic, ideally at the same rate for all areas of the part when it is designed with consistent wall thickness. When injection molding simple, uniform parts conventional cooling typically doesn’t pose any challenges, as all areas of the part generally cool at a similar rate.

However, if a part design is geometrically complex, then the part may not cool at an even rate in all areas, resulting in potential warpage or longer cooling cycles to ensure solidified parts before ejection. The truth is that in today’s world with increasingly complex part geometries, perfectly uniform cooling rates are difficult to attain. In the case of low volume runs, the inefficiencies of having a slightly longer cooling cycles can be negligible and tolerable for molders. However, in the case of high volume runs, these efficiencies can be opportunities to improve productivity or reduce waste. The resulting efficiency of conformal cooling depends on many factors, from the design of the cooling channels, the design of the part, the mold design and even the molding recipe. When done properly, conformal cooling solutions can improve tooling output by 50% or more. 

Conventional Cooling

Conformal Cooling

Including conformal cooling channels in the mold tooling will help address hot spots that result in warpage, resulting in better quality parts with less material waste and fewer defects. 

Faster Cycle Times

In addition to achieving a better quality end result with a lower risk of defects, conformal cooling channels often significantly decrease mold cycle times. In the example below, conformal cooling was used to reduce the cycle time of this high-volume plastic component by almost 40%, increasing mold productivity by nearly 50%.

Is Conformal Cooling Right for Your Needs?

Including conformal cooling channels in injection mold tooling is popular across industries and product types, particularly in the life sciences, and consumer products sectors where parts with complex geometries or high mold volumes are common. If you plan to produce a large volume of parts via injection molding and are concerned about warpage, designing your injection mold tooling with conformal cooling may be the right solution to help with cycle times and lower part costs. In order to ensure that the channels are properly designed for your part’s geometry and specific application, it is imperative to work with an experienced tooling designer who is knowledgeable about how to integrate these novel approaches into high precision tooling.

At SyBridge, our engineers are experts in the injection molding and tooling design processes, and have worked with companies across diverse industries to help them achieve incredible results when it comes to improving mold productivity, reducing defects, and producing higher-performing parts. Whether you already have a mold design that you believe would benefit from the addition of conformal cooling channels or you’re working on the design for a new part or product, our team is here to help.

Contact us to speak with an injection mold tooling design expert and discover if conformal cooling is right for your injection mold tooling needs.

The post Conformal Cooling: Higher-Quality Parts, Faster Injection Molding Cycle Times appeared first on SyBridge Technologies.

Many 3D printed parts aren’t 100% ready straight out of the printer, which is where additive post-processing comes in. Post-processing techniques like sanding and smoothing can improve the look and feel of your part, but other post-processing techniques such as the application of metal inserts, enhance its mechanical properties or geometric accuracy. In some cases, post-processing inserts may need to be added to ensure that a part functions as intended, meets its design specifications, and is ready for customer use.

Additive post-processing inserts serve different purposes, including allowing for printed parts to be fastened to other components, eliminating the need for rivets or adhesives, and helping to streamline the manufacturing process. Since metal is more durable than plastic, certain inserts can even increase part durability, meaning that 3D printed plastic products can be repeatedly assembled and disassembled without damage.

Three are three general types of additive post-processing inserts available: press-fit inserts, heat-staked inserts, and Helicoil inserts. Each insert type is better suited to different 3D printing processes and use-cases: with that in mind, we’re here to help you understand which is the right fit for your project.

Additive Post-Processing Inserts

Press-Fit Inserts

Press-fit is the most common additive post-processing insert type, and is best suited to Carbon Digital Light Synthesis (DLS), HP Multi Jet Fusion (MJF), and stereolithography (SLA) parts. While tapping a part or integrating threads into its design may be an option for 3D-printing projects, plastic threads will wear or break down relatively quickly compared to metal press-fit insert threads. With that issue in mind, press-fit inserts are often used in cases that require high load-carrying capabilities and durability, such as 3D-printed plastic housings, casings, consumer electronics, and other parts that need to accept screws for assembly.

To use a press-fit insert, you’ll need to design your part with a hole, or drill one after the print is complete. Adding the insert will be relatively easy once you have your hole: press-fit inserts are tapered, so they will self-align as they are pressed in. Instead of tapping the hole or melting the plastic before installing an insert into a 3D-printed part, you can simply use a hammer or arbor press to set it into place. Since press-fit inserts often have knurled outer surfaces, they will stay in place once inserted.

Heat Staked Inserts

It’s also possible to use heat-staked inserts with additive parts. Best suited for MJF and FDM printing projects, heat staking involves heating the insert to melt the plastic, and pushing it into place as it cools. Raising and cooling the temperature of 3D plastic components will enable the material to re-form around the insert, creating a strong bond with the printed part. You’ll need to pay attention to how much heat and pressure you apply when installing heat-staked inserts in order to achieve the best results. 

Heat staking not only reduces a part’s complexity by eliminating the need for CAD thread design or rivets, but increases its durability and improves cosmetic appearance. Threaded inserts that have been heat-staked (rather than 3D printed or tapped) will also have greater pull-out strength and be able to better resist stripping, pull-out loads, and torque-out loads. As a result, using heat staking to fix metal inserts and fasteners into 3D printed parts is a common practice in many industries, including the automotive, telecom, and appliance industries, and the process is used on everything from electronic enclosures to appliance dials.

Helicoil Inserts

Helicoil inserts are traditionally used in metal parts but can also be used in FDM 3D prints, regardless of whether a part has a 3D printed thread or a traditionally drilled and tapped hole. Also known as helical inserts and screw thread inserts (STI), Helicoil inserts are coiled wire inserts with coils that are wider than the hole into which they are inserted. To install a Helicoil insert, you’ll need to drill and tap, or 3D print, a threaded hole, before screwing the insert onto an installation tool and installing it. The coil will then expand, forming a tight seal against the existing threads.

There are several types of Helicoil inserts available. Stanley Engineering, for example, offers HeliCoil threaded wire inserts that provide internal threads for standard-sized fasteners and screw locking wire inserts that offer permanent conventional screw threads. Stanley Engineering also produces free-running wire inserts with threads that can be used from both ends, and tangless threaded inserts that are wear-resistant and eliminate the need for tang retrieval.

Metal Helicoil inserts are strong, durable, and resistant to heat. They also prevent threaded holes from wearing out, and so can lengthen a 3D printed part’s lifespan. Helicoil inserts are commonly used in the aerospace, defense, automotive, medical, and telecom industries.

Creating Strong, Durable Parts With SyBridge

Press-fit inserts, heat-staked inserts, and Helicoil inserts offer everything from increased part durability to the possibility of a more streamlined manufacturing process. However, since each insert type is best suited to different project requirements, incorrect installation can damage plastic parts and end up increasing production times and costs. Given the importance of inserts to certain projects, and their associated challenges, it makes sense to work with an experienced manufacturer like SyBridge to ensure that you select the right insert for your needs. 

When you work with SyBridge, you won’t need to be a manufacturing expert to add inserts to your 3D-printed parts, or to navigate any aspect of production. Our team of experts will guide you through the manufacturing process, helping you refine your designs to ensure that your parts are optimized for quality and cost at every stage, and meet your expectations on completion. It’s easy to get your project started: simply create an account and upload your design, and we’ll generate an instant quote for your parts. Prior to generating a quote, you’ll be able to adjust part materials and manufacturing methods, and run automated design for manufacturing (DFM) checks to identify issues with your part. To learn more about post-processing inserts, or any of our manufacturing services, contact us today. 

The post Your Guide to Additive Post-Processing Inserts appeared first on SyBridge Technologies.

All post-processing increases part costs and production timelines, but the right surface finish has the potential to bring your design vision to life. Metal finishing for CNC machined parts typically encompasses a variety of mechanical processes, such as tumbling, brushing, and bead blasting, but metal parts may also be treated with chemical finishes such as passivation and zinc plating.

Amongst many useful results, chemical finishing can remove blemishes from a part, alter its conductivity levels, extend its lifespan, and even increase its resistance to wear and corrosion. Chemical finishes have an array of industrial applications: in the aerospace industry, for example, companies use chemical finishes to increase parts’ durability, improve thermal stability, and slow oxidation. In the consumer goods industry, chemical finishes can be found in the production of everything from enclosures and casings to sporting equipment.

While there are plenty of chemical finishes available, they aren’t necessarily interchangeable between materials. In fact, every chemical finish is typically compatible with specific materials and offers its own advantages and disadvantages. In this guide, we’ll explore several common chemical finishing processes so that you can decide which will work best for your CNC manufacturing project.

Choosing Your Chemical Finish

When choosing a chemical finish for your part, you’ll need to think about both compatible materials and end use. This means considering an array of contextual factors, including: 

• The environment your part will be used in
• Whether it requires conductive or insulating properties
• How much weight it will need to bear
• How much wear it will need to withstand
• Tolerance requirements
• Color and transparency requirements
• Surface finish standards
• Any other relevant or desired properties.

To help you evaluate your options, here are some common chemical finishes and their compatible materials:

Let’s take a closer look at these chemical processes, how they work, and how they might benefit your project. 

Anodizing

A popular aluminum finishing option, anodizing thickens the natural oxide layer on part surfaces, creating an anodic oxide film that confers increased protection and improved aesthetics. In the case of aluminum, to form the anodized protective layer, you’ll need to bathe your part in an acid electrolyte bath and then apply a cathode (a negatively charged electrode) to cause the solution to release hydrogen. At the same time, the aluminum part (the positively charged anode) will release oxygen, forming a protective oxide layer on its surface. After a part has been anodized, its surface will have microscopic pores which must be sealed with a chemical solution to prevent corrosion and any build up of contaminants. 

Anodized parts are durable and resistant to corrosion and abrasion, which can reduce maintenance costs down the line. The anodized layer is electrically non-conductive and is fully integrated with the aluminum substrate, so it won’t chip or flake away like plating and paint often do. In fact, in addition to sealing, the porous anodized layer can be painted or dyed, and since anodized finishes are non-toxic and chemically stable, they’re also more environmentally friendly. Anodizing isn’t just a finish for aluminum: the process is also possible for titanium and other non-ferrous metal parts. 

There are three different types of anodization:

• Type I (chromic acid anodizing) results in the thinnest oxide layer, which means it won’t change your part’s dimensions. Type I anodized elements will appear grayer in color and won’t absorb other colors well.
• Type II (boric-sulfuric acid anodizing) has better paint adhesion and is slightly thicker than Type I. With Type II anodizing, you can easily create anodized parts that are blue, red, gold, black, or green.
• Type III (hard sulfuric acid anodizing) is the most common form of anodizing. It has the clearest finish, which means it can be used with more colors. It’s worth noting that Type III anodizing results in a slightly thicker finish than Type II anodizing.

The increased durability, abrasion resistance, and corrosion resistance of anodized parts, and the high level of dimensional control that the process offers, makes anodizing particularly popular in aerospace and construction. Beyond those industries, anodized metal components are found in a wide variety of applications including curtain walls, escalators, laptops, and more.

Despite its broad applications, there are drawbacks to anodization:

• Anodizing metal will change the dimensions of your part, so you’ll need to consider the oxide layer when determining dimensional tolerances or use chemical or physical masks to ensure specific areas of your part remain untreated.
• It can be challenging to achieve a true color match if your anodized components aren’t treated in the same batch. Color fading may also occur.
• Anodizing a metal part will increase its electrical and thermal resistance. In some cases, this might be the intention, but in others, you may need to use a mask to ensure your part retains its full conductivity in certain sections.
• Anodizing will increase your part’s surface hardness.

Passivation

This popular metal finishing process prevents corrosion in stainless steel parts, helping them retain their cleanliness, performance, and appearance. Not only will passivated parts be far more resistant to rust, and thus better suited to use outdoors, they’ll also be less likely to pit, last longer, be more aesthetically pleasing, and more functional. Accordingly, passivation is used across a variety of industries, from the medical industry where sterilization and longevity are key, to the aerospace industry where businesses seek high steel quality and tight dimensional tolerances.

Passivation involves the application of nitric or citric acid to a part. While nitric acid has traditionally been the typical choice for passivation, citric acid has recently increased in popularity because it can produce shorter cycle times, and is safer and more environmentally friendly. During the passivation process, parts are submerged in an acid-based bath to remove any iron and rust from their surfaces without disturbing the chromium. The application of acid to stainless steel removes any free iron or iron compounds from its surface, leaving behind a layer composed of chromium (and sometimes nickel). After exposure to the air, these materials react with oxygen to form a protective oxide layer. 

It’s important to bear in mind that passivation can extend part production time. Before a part can be passivated, it must be cleaned to remove any greases, dirt, or other contaminants, and then rinsed and soaked (or sprayed). While submersion is the most common passivation method because it offers uniform coverage and can be completed quickly, an acidic spray may be used as an alternative. 

Black Oxide Coating

A finish for ferrous metals like steel, stainless steel, and copper, the black oxide coating process involves immersing parts in an oxide bath to form a layer of magnetite (Fe₃O₄), which offers mild corrosion resistance.

There are three types of black oxide coating:

• Hot black oxide: The hot black oxide coating process involves dipping a part into a hot bath of sodium hydroxide, nitrites, and nitrates in order to turn its surface into magnetite. After bathing, parts will need to be submerged in alkaline cleaner, water, and caustic soda, and then coated with oil or wax to achieve the desired aesthetic.
• Mid-temperature black oxide: Mid-temperature black oxide coating is very similar to hot black oxide coating. The main difference is that coated parts will blacken at a lower temperature (90 – 120 °C). Since this is below the boiling point of the sodium and nitrate solution, there’s less need to worry about caustic fumes.
• Cold black oxide: While hot and mid-temperature black oxide coating involves oxide conversion, cold black oxide relies on deposited copper selenium to alter a part. Cold black oxide is easier to apply but rubs off more quickly and provides less abrasion resistance.

Parts that have received black oxide coating will have greater corrosion and rust resistance, be less reflective, and will have much longer life cycles. The oil or wax coating will add water resistance and may also make your parts easier to clean by preventing harmful substances from reaching the metal interior. Black oxide coating will also add thickness, making it ideal for drills, screwdrivers, and other tools that require sharp edges that won’t dull over time.

Chem Film

Chem film, also known as chromate conversion coating, or by its brand name Alodine®, is a thin coating typically used on aluminum (although it can be applied to other metals) to prevent corrosion and improve adherence of adhesives and paints. Chem film finishes often have proprietary formulas, but chromium is the main component in every variety. A chem film finish can be applied via spraying, dipping, or brushing, and, depending on product and formula, may be yellow, tan, gold, or clear in color.

While other finishes reduce thermal and electrical conductivity, chem film finishing allows aluminum to maintain its conductive properties. Chem film is also relatively cheap and, as noted, provides a good base for painting and priming (for additional time-saving benefits). Since it’s prone to scratches, abrasion, and other superficial damage, however, chem film isn’t ideal for projects in which aesthetic appearance is a top priority.

Electropolishing

Electropolishing is an electrochemical finishing process commonly used to remove a thin layer of material from steel, stainless steel, and similar alloys. During the electropolishing process, a part is submerged in a chemical bath and an electric current is applied to dissolve its surface layer. Various parameters affect the part’s finish, including the chemical composition of the electrolyte solution, its temperature, and the part’s exposure time.

Electropolishing generally removes between 0.0002 and 0.0003 inches from an object’s surface, leaving smooth, shiny, and clean material behind. Other benefits of electropolishing include improved corrosion resistance, increased part longevity, improved fatigue strength, a lower coefficient of friction, reduced surface roughness, and the elimination of surface defects such as burrs and micro-cracks.

Electropolishing is compatible with steel, stainless steel, copper, titanium, aluminum, brass, bronze, beryllium, and more. It’s worth noting that electropolishing is faster and cheaper than manual polishing, though it still takes time and won’t remove 100% of rough surface defects. 

Electroplating

Electroplating is effectively the reverse of electropolishing. Instead of removing a layer of metal to achieve a finished surface, electroplating deposits an additional outer layer, increasing a part’s thickness. Compatible with cadmium, chrome, copper, gold, nickel, silver, and tin, electroplating creates smooth parts that experience less wear and tear over time thanks to their additional protection from corrosion, tarnishing, shock, and heat. Electroplating can increase adhesion between the base material and its additional outer coating, and, depending on the type of metal used, can make your part magnetic or conductive.

In contrast to other CNC machining finishes, electroplating isn’t particularly eco-friendly since it creates hazardous waste that can seriously pollute the environment if disposed of improperly. Electroplating is also relatively costly, as a result of the metals and chemicals (and other necessary materials and equipment) that it requires, and can be time-consuming, especially if a part requires multiple layers.

Chrome Plating

Chrome plating, or chromium plating, is a type of electroplating that involves adding a thin layer of chromium to a metal part to increase its surface hardness or resistance to corrosion. The addition of a chrome layer can make cleaning a part easier and improve its aesthetics, and nearly all metal parts can be chrome plated, including aluminum, stainless steel, and titanium.

The chrome plating process generally involves the degreasing, manual cleaning, and pretreatment of a part before it is placed in a chrome plating vat. The part must then stay in the vat long enough for the chrome layer to reach a desired thickness. Since the process consumes electricity, and involves multiple steps, chrome plating is a relatively expensive finishing process.

Polytetrafluoroethylene (Teflon™) Coating

Polytetrafluoroethylene (PTFE) coating, commonly known as Teflon™, is available in powder and liquid forms, and is used across the industrial landscape. Some PTFE applications only require one coat, but others need both a primer and a topcoat to ensure maximum protection. The finish can be applied to a range of metals including steel, aluminum, and magnesium.

PTFE-coated parts have non-stick surfaces, a low coefficient of friction, and are highly resistant to abrasions. Since PTFE coating has low porosity and surface energy, coated parts will be resistant to water, oil, and chemicals. PTFE can also withstand temperatures up to 500°F, can be easily cleaned, and offers great electrical insulation and chemical resistance.

Due to its chemical resistance and non-stick properties, PTFE is often used to coat fuel pipes and to insulate circuit boards in computers, microwaves, smartphones, and air conditioners. It is also commonly used to coat medical tools and equipment, and cookware. Although it is popular across industries, the PTFE coating process is relatively expensive and isn’t as long-lasting as other chemical finishing options.

Electroless Nickel Plating

Electroless nickel plating refers to the addition of a protective layer of nickel-alloy to metal parts. In contrast to the electroplating process, which involves an electric current, electroless nickel plating involves the use of a nickel bath and a chemical reducing agent like sodium hypophosphite to deposit a layer of nickel-alloy (often nickel-phosphorus) onto parts. The nickel-alloy deposits uniformly, even on complex parts with holes and slots. 

Parts finished with nickel plating have increased resistance to corrosion from oxygen, carbon dioxide, salt water, and hydrogen sulfide. Nickel-plated parts also have good hardness and wear resistance and, with additional heat treatment, can become even harder. Electroless nickel plating is compatible with a variety of metals, including aluminum, steel, and stainless steel. 

Electroless nickel playing has its challenges. Common problems include the build up of contaminants in nickel baths, rising phosphorus content, and subsequent reductions in plating rates. Additionally, the wrong temperature or pH level can create coating quality issues like pitting, dullness, and roughness. Electroless nickel plating isn’t suitable for rough, uneven, or poorly machined surfaces, and parts will need to be cleaned of soaps, oils, and dirt before the plating process can begin.

Different types of electroless nickel plating coatings are categorized by the percentage of phosphorus in the alloy by weight. Different levels of phosphorus content also offer different levels of corrosion resistance and hardness:

• Low phosphorus nickel (2 – 4% phosphorus): Low phosphorus electroless nickel has an as-plated hardness between 58 and 62 Rc, and is highly resistant to wear. It has a high melting point and good corrosion resistance when exposed to alkaline conditions. Low phosphorus electroless nickel deposits are compressively stressed and are usually more expensive than medium and high phosphorus nickel.
• Medium phosphorus nickel (5 – 9% phosphorus): Medium phosphorus nickel plating offers a middle ground between low and high phosphorus nickel. It is resistant to corrosion in alkaline and acidic environments and has a fast deposition rate (18 to 25 µm per hour). The as-plated hardness of medium phosphorus nickel can be anywhere between 45 and 57 Rc, and the plating can be heat treated to reach 65 to 70 Rc.
• High phosphorus nickel (>10% phosphorus): Since high phosphorus deposits of electroless nickel plating are amorphous, parts won’t end up with phase boundaries or grain, increasing their corrosion resistance and making them ideal for use outdoors or in extreme environments. High phosphorus electroless nickel plating also offers ductility, high thickness, and stain resistance, and will make it easier to polish or solder your final product.

Zinc Plating

Zinc plating, or zinc chromate, is a popular chemical finish that protects steel parts from moisture and corrosion. Zinc-plated products have increased longevity, improved aesthetic appeal, and a more uniform appearance. Zinc plating can also alter a part’s color to silver-blue, yellow, black, or green. Another significant benefit of zinc plating is its potential to protect a part’s surface for years: even if the coating becomes scratched, the zinc will react to the atmosphere and quickly oxidize. Since zinc is chemically susceptible to acids and alkalis, however, zinc plating may not be sufficient for parts destined for wet or extremely humid environments.

There are a few different types of zinc plating. Electro-galvanization requires an electrical current to coat the part in a thin layer of zinc, whereas hot-dip galvanization requires parts to be submerged in a hot zinc bath. Electro-galvanization is the cheaper process, but hot-dip galvanization is better for parts that will be used in aggressive environments or that will experience a lot of wear.

Following the zinc plating process, parts can undergo a secondary procedure for increased protection and improved performance. The ASTM B633 standard, the most widely used standard for zinc plating, includes four types of zinc plating:

• Type I: Type I has no supplementary treatment.
• Type II: Type II involves a colored chromate treatment.
• Type III: Type III uses a colorless chromate treatment.
• Type IV: Type IV uses a phosphate conversion treatment.

Achieving Quality Finishes With SyBridge

Chemical finishing offers numerous ways to achieve the surface quality and performance levels that you need for your part, but not every finishing process will be suitable for every material and end-use. To determine which chemical finish is right for your part, you’ll need to have a strong understanding of critical factors, such as how much corrosion, friction, and wear resistance your final part needs, the environment in which it will be used, and its required conductive or insulative properties. 

Given the importance of those considerations, it’s worth finding a manufacturing partner to help you select a suitable finish, and ensure that it offers the best quality and cost efficiency possible. At SyBridge, our expert team of designers and engineers can offer insight not just into the chemical finishing process, but material selection, tooling, and suitable CNC technologies. If you want to know more about the finishing options available for your next CNC machining project, get in touch with us today. If you’re ready to get started, create your account, upload your designs to get an instant quote, and start making new parts and products in just a few simple steps.

The post A Guide to Chemical Finishes for CNC Machined Parts appeared first on SyBridge Technologies.

Prototyping is an essential part of the product development process, but it isn’t just limited to rapidly-produced proof of concept models. Prototyping also comes in handy throughout various phases of a project’s development, including engineering, quality assurance, focus testing, and marketing.

Prior to the introduction of 3D printing, the production, assembly, and presentation of functional prototypes was a long, expensive, and sometimes impossible process. Today, however, a range of 3D printing technologies has made those processes quicker and easier, with both the cost of part production and assembly times reduced significantly. Even with the benefits that 3D printing brings to the prototyping process, it’s still important to understand how it can be optimized during prototyping, so that your project comes together on time, even when you’re facing a critical deadline. 

3D Printing Prototyping Phases Explained

Product Conceptualization

The product conceptualization phase occurs early in the product development life cycle, and involves the relatively swift creation of a model that conveys a design idea. In this phase, speed is a top priority, which makes 3D printing the perfect technology to bring your designs to life.

During production conceptualization, a 3D printer can be used to quickly build one (or several) prototypes to help sell an idea to internal and external stakeholders, and to develop a sales model. These physical mockups will vary in cost depending on materials used and by production requirements. A prototype printed from polylactic acid (PLA), for example, will cost less than one made from ULTEM (PEI). Similarly, while a prototype printed with a taller layer height will be faster and less expensive to produce than one with a shorter layer height, it will look less polished.

Proof of Concept Demonstration

Proof of concept prototypes are essentially working models that demonstrate functionality and prove that your design will fulfill its intended purpose. 

A proof of concept prototype does not need to be produced with the same aesthetic standard as a finished product. During this phase, the emphasis should be on functionality; to save time and money, you may be able to use off-the-shelf components in your proof of concept model, or make the model with a slightly larger layer size than you would for a more advanced prototype. 

While it is possible to use fused deposition modeling (FDM) for proof of concept prototypes, it may be best to use an additive process that offers a little more accuracy, such as Carbon® Digital Light Synthesis™ (DLS) or HP Multi Jet Fusion (MJF). For some prototyping projects, it may even make sense to look beyond additive and explore different manufacturing processes during the proof of concept phase. 

Industrial Design Implementation

The industrial design implementation phase is when you evaluate the ergonomics, aesthetics, usability, and scale of your prototype so that it will closely simulate your final product. 

During this phase, it’s important to use a similar material to your final product in order to better understand its overall ease of use, appearance, and ergonomics. For example, you might use FDM to create parts with the same thermoplastic materials that you would use in the injection molding process so that you don’t need to create an expensive and time-consuming mold but can still get a sense of the look and feel of your final product. Similarly, you might opt to use an HP MJF printer to 3D print a nylon part and coat it with nickel as a finishing process, instead of CNC machining an entirely metal prototype.

Functional Testing and Feedback

The functional testing and feedback phase is when you create functional prototypes to see if your product will actually work.

Functional prototypes generally require end-use durability and a higher-quality surface than parts produced in earlier prototyping phases, and can be sent out for stakeholder feedback in order to improve designs for your next iteration. A hybrid of proof of concept and industrial design prototypes, functional prototypes can be used to test everything from thermal performance and aerodynamics to mechanical performance and properties. Since stakeholder feedback often leads to additional design revisions, it’s best to create functional prototypes before investing in costly tooling in order to avoid mistakes and modifications that stretch your budget and project timeline. 

Pre-Manufacturing Research Modeling 

The pre-manufacturing research modeling phase refers to the creation of research prototypes that look and function like the finished product.

Creating research prototypes, enables critical stakeholders and early adopters to experience your product before the final version is released. Pre-manufacturing research prototypes will be more refined than functional prototypes, yet produced in lower volumes than final production runs. Feedback from stakeholders and early adopters during this phase could mean additional design changes.

Pre-manufacturing research prototypes also enable you to assess parts in the context of design for manufacturability (DFM) or assembly, and then optimize your design for high-volume production. Even the slightest change in product design can significantly impact costs, particularly when dealing with high volumes of parts.

The Advantages of Using 3D Printing for Prototyping

3D printing has plenty to offer when it comes to prototyping. Not only can you use 3D printed prototypes to better understand the form and function of your part, and to optimize your design accordingly, but you won’t break the bank creating them since there’s less need for expensive tooling than, for example, injection molding.

Speed is a notable advantage of prototyping via 3D printing. Instead of waiting weeks or months for a part (as you might with CNC machining or injection molding), a 3D printed prototype can be in your hands in days or even hours. The pace of 3D printing prototype production enables designers to swiftly move from iteration to iteration until a final design is perfected. 3D printers can also handle complex geometries: whether you’re creating a part with a hollow interior, holes, or moving elements, 3D printing is typically a reliable way to create functional, dimensionally-accurate prototypes.

3D printing technology also offers access to a wide range of industrial materials, from performance-grade thermoplastics to light-sensitive resins. That versatility can open up design possibilities for your prototypes: you could use 3D printing technology to create multi-material parts, for example, or use water-soluble support materials to achieve even more complex geometries. 

Tackling the Prototyping Phases of 3D Printing With SyBridge

While 3D printing offers clear benefits during the various phases of prototyping, it may not make sense for you to invest in a 3D printer yourself. 3D printing requires a significant investment in equipment and materials, and requires a level of additive manufacturing technical expertise that might be similarly costly to acquire. With those considerations in mind, it’s entirely possible to minimize the financial and technical challenges of 3D printing by working with a manufacturing partner. 

When you work with SyBridge, you’ll have access to cutting-edge 3D printing technology, an array of additive materials, and the skills you’ll need to deliver on your vision. Our team of expert designers and additive manufacturing engineers will guide you through the prototyping process, ensuring that you optimize your project for quality and cost during every phase. And getting your prototyping project started is easy: simply create an account and upload your design to get an instant quote.

Additionally, you’ll be able to explore different materials, run DFM checks, and store iterations of your prototype parts in the cloud. If you’re ready to get started but want to find out more about your 3D printing prototyping options, contact us today to speak with one of our experts to get the assistance you need to make your ideas a reality.

The post Exploring the Prototyping Phases of 3D Printing appeared first on SyBridge Technologies.

In the manufacturing business, more money put into production generally means less profit or higher prices for customers. But careful planning and informed decision making about your design will help save time and money during the CNC machining process.

CNC machining costs can be divided into two main buckets: non-recurring costs and piece costs. Non-recurring costs refer to all of the upfront costs required to get any production run (large or small) off the ground; these costs are amortized over the production quantity. Piece costs are expenses associated with each individual part, and scale with quantity. The bottom line cost to manufacture a single part, taking into account all cost buckets, is often referred to as the fully burdened part cost.

To put this in mathematical terms: 

Fully Burdened Part Cost = Non Recurring Costs / Quantity + Piece Costs

Non recurring costs include:

• Part design 
• Planning (manufacturing process, inspection, etc.)
• CAM programming
• CMM programming 
• Workholding, fixtures, gauges, and tooling identification and sourcing

Piece costs include:

• Machine time
• Labor time (loading and unloading parts)
• Consumable tooling
• Raw material
• Cleaning, deburring, and finishing 
• Manual inspection

Following the equation above, in lower volume runs, non-recurring costs are amortized over fewer parts, which means the expense is higher per part. For example, if the non-recurring costs for a job are $5,000, and the production quantity is 100 parts, then each part will have a burden of $50 for non-recurring expenses. On the other hand, if that same job is ordered for a quantity of 200 parts, this would result in a non-recurring burden of just $25 per part, a potentially significant cost delta. The good news is that you can minimize CNC machining costs for shorter production runs by optimizing your part designs.

Design tips for short production runs

To maximize your time and budget, try these design tips for short production runs:

Use standardized, simple designs

Keep your design as simple and standardized as possible. Overly complicated part designs can require multiple manual rotations and repositions, more expensive CNC systems, or specialized tools. With this in mind, it may be worthwhile to break up a complex piece into simpler components that can be assembled later.

You’ll also want to:

• Design standard-sized holes: The deeper the hole, the more complex the metal chip evacuation process, and the more expensive your part. Try to make each hole’s depth no more than five to six times the drill’s diameter to ensure your machinist can quickly evacuate the metal chips. Also, make sure to use standard drill sizes when designing your holes or you may end up needing to purchase a custom tool, which can drive up costs and overall production time further.
• Use standard threads: As with drill sizes, using standard thread depths and diameters can save time and money. In practice, this means simply using an existing thread class instead of creating a custom thread via CNC machining or 3D printing. Try to use the H2 thread tolerance, since H3 is tighter and more expensive to create. Also, it’s best to keep your thread depth no deeper than required by your part’s functional and structural specifications.
• Design with standard stock sizes in mind: You can also cut costs and machine times by designing your parts to align with standard stock sizes. Instead of ordering a larger piece of material only to have to machine it down, your machinist will be able to buy a standard stock piece and then make few (if any) changes before starting on your part. Beyond choosing standard stock sizes, it’s also a good idea to allow a large enough tolerance so that the outside of the part does not need to be machined.
• Use loose tolerances: Tight tolerances can require specialized manufacturing processes or secondary operations, and can increase set-up, machining, and inspection time and cost. With that in mind, your part’s tolerances should only be as tight as required by functional and structural constraints.

Avoid thin walls, tall walls, and narrow pockets

CNC machining can be a delicate and time-intensive operation, especially if you have thin walls, tall walls, or narrow pockets.

Since they can increase the risk of cutter deflection, deformation, compromised surface finishes, and part failure, and make it difficult to meet specified tolerances, thin walls are generally less stable and more expensive to machine. Beyond those considerations, your machinist may need to take numerous passes over a part to create a thin wall without accidentally fracturing or snapping it with excessive vibrations, which will, of course, further drive up machining times and costs.

There are options for addressing the increased machining times, higher production costs, and fracture risks associated with thin walls. For example, if you have a metal part, try to design walls that are at least 0.8 mm thick. For plastic parts, try to aim for walls at least 1.5 mm thick. Similarly, you’ll want to avoid including tall walls, deep cavities, and narrow pockets in your part, since these features require longer cutting tools and the removal of more waste material. Like the problems associated with thin walls, these issues can lead to increased cutting tool deflection, chatter, inaccuracies, reduced tool life, and sub-par surface finishes, all of which drive up the final part cost.

Avoid unnecessary text or finishing processes

Adding text to your part will enable you to clearly number components, include a description, or apply a company logo. While machined text looks aesthetically pleasing, and can be functionally useful, it’s an expensive and time-consuming process since you’ll need to trace each character with a small ball end mill or engraving tool. Unfortunately, including raised text on a part is even slower and costlier since even more material will need to be milled away from the part to achieve the effect.

As an alternative to machining, if your part requires text, lettering, or a logo, you may be able to save time and money with a post-production surface finishing method. For example, silk screening, laser marking, rubber ink stamping, and painting will all enable you to add text to your parts faster than direct engraving. Of course, given that adding any CNC finishing process will increase your parts’ turnaround time and overall costs, it’s best to avoid text and other non-critical finishing processes whenever possible.

Choose the proper material

Material selection is important in both long and short production runs since using the wrong metal or plastic for your parts can drastically increase project costs. Some materials are more difficult to machine than others, which means longer turnaround times and higher machining costs. Even if two materials are equally machinable, the chances are that one will be more expensive than the other.

For example, while titanium is ideal for aerospace applications, it’s expensive and difficult to machine. On the other hand, softer, less costly metals, such as aluminum, are easier to machine and strong enough for everything from airplane parts to architectural components. Similarly, if you want to create a plastic part but don’t require the strength or high heat resistance of polyetheretherketone (PEEK), you can save money by using acrylonitrile butadiene styrene (ABS) or another high-performance engineering thermoplastic.

To put it simply, if you don’t really need the properties of an expensive and/or rare material, you should use a less expensive and/or more common material. As an added benefit, using a more readily available material also likely means a reduction in your parts’ overall lead time. It’s worth applying this mentality during the prototyping phase, too; for example, if you only need to create a proof-of-concept model, you should use the least expensive plastic that will still demonstrate the feasibility of your idea.

Additive manufacturing as an alternative for short production runs

While designing with CNC machining lead times in mind can help reduce turnaround and cut costs, depending on your material requirements and the size of your run, additive manufacturing might represent a better option

In contrast to CNC machining, which is a subtractive process that involves cutting away material to shape a final product, the additive manufacturing process builds parts layer by layer. Additive manufacturing is typically far less labor-intensive than CNC machining, sometimes only requiring limited mid-production repositioning and limited post-processing to enhance a part’s functionality, or to achieve a desired finish. Like CNC machining, additive manufacturing can be used to make metal parts, but plastic additive manufacturing is far more common. In fact, many of the plastics used in additive manufacturing are mechanically equivalent to those used in injection molding. 

Generally, additive manufacturing is a better choice for extremely low-volume production runs or for projects in which finished parts or prototypes must be delivered fast, and where tolerance requirements are not tight. By contrast, CNC machining is more appropriate for low-volume production runs with part quantities in the higher double digits or low hundreds, or in projects that have high tolerance requirements.

Working with an experienced manufacturing partner

Each of our design tips for short production runs can help you ensure that your production process is as smooth, cost-efficient, and fast as possible. However, there’s a lot to keep track of when optimizing parts for low-volume production, so working with a trusted manufacturing partner is also a valuable opportunity to take some of the weight off your shoulders.

From design through fulfillment, when you work with SyBridge, our team of experienced engineers will provide you with the support you need to make your project possible. Our cloud-based tools are designed to help you pinpoint design flaws, determine optimal order quantities, and find the right material for your part’s specific application. Simply create an account and upload your part files. We can generate instant quotes for both additive manufacturing and CNC machining projects, which means you can get started making your new parts and products today. Contact us today.

The post Design Tips for Low-Volume CNC Machining Production Runs appeared first on SyBridge Technologies.

In 2021, the global Computer Numerical Control (CNC) machine market size was $56.40 billion. Given how fast, precise, and automated this manufacturing technology is, it’s hardly surprising that the global machine market is expected to grow in the coming years. As the demand for CNC machining grows, the demand for Swiss machining, a manufacturing process that falls under the overall umbrella of CNC machining, will also rise.

As with traditional CNC machining, Swiss machining is used with metal and plastic, offers fast production times, and can produce complex parts with tight tolerances. It’s an incredibly efficient, precise, and repeatable manufacturing process, though it differs in several ways from traditional CNC machining.

In this guide to CNC Swiss machining, we’ll go over what you need to know to decide whether Swiss machining is best for your project.

What is Swiss Machining?

Originally developed to produce intricate watch parts for the Swiss watchmaking industry in the late 19th century, Swiss screw machines required a skilled operator who could turn handles and push levers to form the desired part. However, thanks to today’s CNC technology, Swiss machining is highly automated and can repeatedly produce complex geometries at tight tolerances with extremely fast cycle times.

As a subset of turning machines, also known as lathes, Swiss machines have stationary tools and a workpiece that can turn and move along the Z-axis, allowing for the creation of round and cylindrical parts. However, its sliding headstock and guide bushing set Swiss machines apart from other turning machines. The sliding headstock feeds the bar stock through a guide bushing, which supports and stabilizes the bar stock near the cutting point. This helps prevent workpiece distortion and enables the machine to accurately create different diameters, complex holes, hex edges, slots, and threads without the need for multiple setups or additional equipment.

When it comes to making parts, Swiss machining is the ideal production method for manufacturing high volumes of small components that require complex turning. Swiss machines are also better suited for machining long parts than traditional CNC turning machines, as they are less likely to cause deflections. 

Key Differences Between Traditional CNC Turning and Swiss Machining

The main difference between traditional CNC turning and Swiss machining is that Swiss machines have a moveable headstock that enables the workpiece to spin and move along the Z-axis, whereas the workpiece remains stationary when using conventional lathes.

Additionally, traditional CNC lathes generally have two, three, or four axes, but Swiss machines often have five, seven, or more axes, enabling operators to quickly machine even the most complex parts. Instead of performing multiple operations or using several setups on numerous machines, manufacturers can often do the job with one Swiss machine and fewer setups. It’s also worth noting that many Swiss machines can perform several tooling operations simultaneously, whereas traditional lathes usually complete one operation before moving on to the next, which can help further accelerate production.

By using a Swiss machine, companies can enjoy a reduction of secondary operations and tool changes, reduced labor costs, and faster turnaround times, all without sacrificing part quality. Since the bar stock is firmly supported, tolerances are tight and complex parts with thin walls or delicate features can be repeatedly manufactured.

Industry Applications for Swiss Machining

Swiss machining was initially used to create the tiny, intricate parts used in watches, and it’s still used to create long, small, or slender turned components across various industries. Its speed, accuracy, and relatively low costs have kept Swiss machining popular.

For example, Swiss machining’s high level of accuracy makes it an ideal manufacturing technology for the defense sector, where small, complex geometries with tight tolerances are often required for military hardware. 

Swiss machining also has plenty of applications in the medical industry, where manufacturers can use Swiss machines to produce everything from electrodes to anchors to surgical tools.

In the aerospace industry, Swiss machining can produce components that meet the extreme precision required by the industry’s rigorous demands. The technology can be used to create everything from mechanical components for spacecraft motors to the cockpit controls’ electrical components.

Similarly, Swiss machining’s ability to produce quality and precise parts makes it a popular manufacturing process in the automotive industry. Here, companies use Swiss machines to fabricate bushings, pins, brake system and suspension components, and more.

Essentially, Swiss machining is an excellent production method for manufacturers who need to quickly produce a high volume of small, accurate parts with complex geometries and high-quality finishes for a relatively low cost.

Design Tips for CNC Swiss Machining

While CNC Swiss machining differs from traditional CNC machining, many best practices should still be kept in mind when designing your part to reduce machining time and costs as much as possible. For example, make sure you remember to:

• Ensure your drawings are accurate and clear: You need to have legible and precise drawings to ensure your operator can quickly and correctly understand and machine your part. Include dimensions, tolerances, and material and finish information.
• Use standard-sized holes: Incredibly small or deep holes can make machining more difficult and expensive, so it’s best to use standard-sized holes whenever possible.
• Avoid sharp corners: Whether you’re using a traditional CNC lathe or a Swiss machine, your drill bits will be round, which means it will be incredibly difficult to produce sharp inner corners. While you can achieve sharp inner corners using methods like electrical discharge machining, this can be expensive and time-consuming. Thus, it’s best to always design your parts with rounded corners, as the drill bit will automatically leave an inside corner radius. To avoid chatter and premature tool wear, make sure your corner radius is slightly larger than the common trade sizes of tool diameters, such as 3 mm or ⅛ inch, for example.
• Only include the necessary tolerance: Including unnecessarily tight tolerances can drive up machining time and overall part costs, so it’s best to only assign strict tolerances to areas where they truly matter.
• Pay attention to wall thickness: While it’s possible to machine thinner walls with Swiss machines, it’s still best to avoid designing your parts with thin walls, as they can cause chatter, resulting in less-accurate parts with reduced surface quality. When it comes to plastic parts, thin walls can also result in warping and softening.

CNC Swiss Machining with SyBridge

Swiss machining is a fast, accurate, and cost-effective manufacturing method that’s ideal for creating large quantities of small parts that require complex CNC turning. However, as with any CNC process, it’s best to keep the above tips in mind when designing your parts to ensure your machining time and costs are as low as possible.

Whether Swiss machining is the ideal manufacturing process for your parts or traditional CNC turning is better-suited for your needs, working with an experienced manufacturing partner like SyBridge can help you make the right decisions to get better quality parts faster. Start making the precision-machined parts you need today — contact us to get started.

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