HP Multi Jet Fusion

RapidMade Develops Techniques to Strengthen 3D Printed Nylon Parts with Reinforced Fibers

Carbon-fiber-reinforced 3D Printed Nylon Part

Carbon-fiber-reinforced 3D Printed Nylon Part

RapidMade recently completed research on investigating a solution to produce custom agricultural parts from 3D printed nylon reinforced with fibers in epoxy polymers. The work was completed with Oregon State University and was funded with an SBIR grant from the USDA.

Additive manufacturing reduces the cost and lead time of individually produced parts. Most printed plastic materials lack the strength needed to replace metal parts. Synthetic and natural fiber reinforcement can increase the strength of these lighter plastic parts making them comparable to metal.  Well characterized design and manufacturing processes are critical to produce reliable composite parts.

Research focused on:

·         structural component designs including materials selection

·         pilot manufacturing process development

·         manufacturing and mechanical component property validation.

Outcomes identified possible techniques for component design and manufacture to:

·         eliminate plastic part anisotropy

·         control warp and residual stresses in composite components

·         verify plastic/epoxy bond strength

·         optimize print orientation

·         improve fiber reinforcement application

·         establish curing cycle and post-processing requirements.

Future research will study part design techniques to:

·         determine best practices

·         create structural and processing analysis rules

·         explore different material options

·         optimize manufacturing processes for small batch production

·         evaluate aging and environmentally induced stress responses.

Component design and manufacture showed positive results in terms of low-cost manufacturing process and performance. Fiber-reinforced parts performed better than the plastic-only reference components with strength comparable to the original metal parts. Data suggest that a reliable method for engineering and manufacturing fiber reinforced composites using printed parts was found. Proof-of-concept agricultural and robotic parts that can replace obsolete and custom equipment were shown to be potential affordable alternatives to the originals.  Design aspects like matching plastic core and fiber reinforcement characteristics for optimal final composite products need to be addressed in detail.

New composite alternatives can be used to:

·         make replacement parts

·         increase field productivity

·         upgrade or reconfigure machinery

·         improve equipment operations and efficiencies

·         manufacture components using more sustainable materials

·         enable local farms to be more independent in part procurement. 

This manufacturing process can enable small production plants to make parts locally as needed.  Future work should build on current results by studying custom design, materials selection, manufacturing process optimization and aging and environmentally induced stress responses.  Specifically, research focused on bonding reliability between printed parts and fiber reinforcement and combining components in a simple, efficient composite manufacturing process.

Work was subdivided into the following areas:

Mechanical Properties and Anisotropy of 3D Printed Parts. Baseline tests measured printed part mechanical properties prior to testing composite fiber components. ASTM standard tests of mechanical properties and microscopic analysis across a range of printers identified part anisotropy. Print parameters were established to limit anisotropy. Additional design parameters must be developed to limit impact on composite part performance.

Characterization of the 3D Printed Plastic-Fiber Reinforcement Epoxy Bond.  Detailed bond tests were performed on parts made using two different fabrication techniques and three alternate fibers. Single lap joints were shear tested to failure to study nylon composite bond response.  Multiple test scenarios characterized the nature of the bond, the minimum overlap requirements and the relative results with different fiber materials. Part failure occurred before the bond confirming the hypothesis. Actual bond strength data was captured. The use of organic fibers as an alternative lower cost composite reinforcement was confirmed.

Composite Manufacturing Process Evaluation. An established composite manufacturing process employed for small batch production was used for testing. Research focused on adapting these techniques to printed materials. Successful composite test parts were created and used for mechanical properties testing. Elements of the composite manufacturing process were investigated to improve the epoxy-nylon bond and to minimize component stress during heat curing. Trials were conducted to further simplify manufacturing techniques and optimize part quality. Work focused on three test components and three alternate fiber reinforcement materials. Iterations evaluated manufacturing process and part quality improvements. Findings were summarized in the published research.

Warping of Components During Curing. The effects of bonding between thin wall printed parts and fiber reinforcement using different configurations was studied. Thin wall components and the ability to assemble larger composite parts from multiple smaller printed parts are critical requirements for farming applications. The work focused on composite cooling times and fiber direction. Non-traditional inverse core sandwich constructions were also studied and tested. Results were positive; additional work will focus on further internal part stress reduction.

Design of Fiber-reinforced Test Components: Three designs were tested: a tractor linkage arm, a compound moment arm and a robotic fruit picker. These parts were selected as they experience different operational compressive and tensile stresses. The fiber reinforced parts were dimensionally comparable to the original metal parts. Mass reduction and low-cost manufacturing were assessed.

Construction and Testing of fiber-reinforced, 3D printed composite parts: Baseline finite element analysis for loading and elastic deformation simulations was performed on part designs. Unreinforced printed parts were mechanically loaded and tested; experimental results were compared to the simulations and test part baselines were created. Loading tests were repeated using fiber reinforced composite parts to characterize mechanical property augmentation due to fiber-reinforcement and the overall part performance. Extensive testing was conducted on all three parts using a range of fiber materials. The results were cataloged and contrasted to establish performance models. The work also analyzed the impact of composite construction methods on finished part mechanical properties.

Impact of temperature cycling on fiber-reinforced, 3D printed composite parts: Cyclical temperature tests performed on all parts using multiple fiber materials determined fiber bonding impact. This work measured bonded composite delamination using non-destructive test methods. Results confirmed that printed part design and fiber reinforcement location can impact composite bonding in response to thermal stress. Minimum printed part thickness must be determined to minimize warping, during the initial curing process and in response to subsequent thermal stress. Printed parts need to be designed and manufactured to account for internal thermal stress factors. Design techniques to improve part structural strength properties need to be included in future work. Finally, reinforcing composites should be selected to have a coefficient of thermal expansion that matches the printed core to minimize thermal stress warping.

To read the complete technical research report go to  https://www.rapidmade.com/resources

Cast Silicone Medical Device Saves Oreo the Goat

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This Spring, RapidMade teamed up with New York-based nonprofit Woodstock Farm Sanctuary for a special project to help a goat named Oreo deal with a unique medical condition.

As reported by the Shawangunk Journal, Woodstock Farm Sanctuary rescued Oreo from a petting zoo in 2015 where she had been neglected. After three happy years at Woodstock, Oreo was hospitalized in 2018 because of a buildup of abdominal fluid.

The issue flared up again this year, and veterinarians found that a tumor was preventing her stomach from functioning properly. When they recommend euthanasia for Oreo, however, Woodstock director Hervé Breuil refused to give up on her.

To help Oreo, Woodstock Farm Sanctuary recruited Dr. Isabelle Louge to develop a valve that would allow fluid to be released from Oreo’s abdomen. The only problem was that such a valve would need to be cast from rubber, which, using traditional technologies, would have been prohibitively expensive and time consuming to manufacture.

Cast Silicone with 3D Printing Tooling

RapidMade was able to help Oreo by deploying a combination of 3D printed tooling and rapid silicone casting. Instead of creating traditional tooling for the injection molding process, we used our Multi Jet Fusion 3D printer to quickly create a 3D printed master pattern. We then used this pattern to create a silicone mold that let us to cast a valve for Oreo in medical-grade silicone.

Not only did this allow us to deliver the valve in a fraction of the time and cost of injection molding, but it also made it possible for Woodstock Farm Sanctuary to create multiple iterations of the valve in a timely manner. Ultimately, we were able to create a product that met Oreo’s needs and was durable enough to stand up to the rough-and-tumble life of a goat.

Quickly Produce High-Quality Cast Rubber and Plastic Parts

Silicone and urethane casting are great options for small- to medium-volume productions that require the versatile materials and finish quality of injection molding. By combining these technologies with 3D printed master patterns, we can create high-quality plastic and rubber parts faster that would otherwise be possible and at less cost. This can benefit clients seeking to produce end-use parts or to create prototypes and first articles during their product development.

If you have a project that you think could benefit from 3D printing or cast silicone, reach out to us to learn more about our services or get started right away with a free quote and project analysis.

Design for Additive Manufacturing Workshop with HP and RapidMade

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Learn how innovative design and HP Multi Jet Fusion 3D printing can improve part quality, reduce costs, and speed up production.

Where: RapidMade | 15883 SW 72nd Ave, Tigard, OR 97224


When: Tuesday, April 9th, 2019 | 9AM - 4PM

Additive manufacturing is rewriting the rulebook for product design, which is why RapidMade is teaming up with HP for a free all-day event about design for additive manufacturing (DFaM) on the HP Multi Jet Fusion. Engineers and product designers are invited to join us for a special workshop led by additive manufacturing experts to learn more about how to get the most from 3D printing.

Here's what you'll learn: 

  • Why HP used the Multi Jet Fusion instead of injection molding to manufacture over 140 functional parts used in each of its new MJF 500/300 3D printers

  • Identifying applications for additive manufacturing across your product lifecycle

  • Training on the fundamentals of effective design for MJF

  • Design strategies for MJF process optimization

  • How the materials behave and what to consider when designing for each of them

  • New design paradigms for additive manufacturing and the required mindset change

  • Designing for value maximization (process and cost)

  • Training on the fundamentals of effective design for MJF

  • Live Design for Additive Manufacturing (DfAM) demo and application examples to inspire you

This free event will feature breakfast and lunch, as well as the opportunity to tour our facilities and consult directly with specialists from RapidMade and HP.

Don’t miss out on this exciting opportunity! Registration is limited, so click the link below to reserve your spot today.

REGISTER HERE

Agenda

8:30 – 9:00 AM Breakfast

9:00 – 9:15 AM Welcome & introduction

9:15 – 9:45 AM Multi Jet Fusion (MJF) basics

9:45 – 10:15 AM Why 3D & case study of HP's adoption of Multi Jet Fusion technology for production parts

10:15 – 10:30 AM Break

10:30 – 11:30 AM Deep dive on designing for additive manufacturing – strategy, guidelines, materials, considerations, machining & threads, bonding, process control, etc.

11:30 AM – 12:00 PM Cases for tooling and final part production – urethane casting, thermoforming, fluidics management, industrial applications & electric vehicle examples

12:00 – 1:00 PM Lunch

1:00 – 3:00 PM Applications discovery workshop

3:00 – 4:00 PM Consult with HP and RapidMade experts on your parts

We look forward to seeing you!

Can't attend?
Get in touch with our 3D printing experts here.

Defox, LLC and RapidMade show how 3D printing can help small businesses

The 3D printed periscope case manufactured by the HP Multi Jet Fusion.

Additive Manufacturing Magazine recently published an article about one of RapidMade’s clients, Defox, LLC, a startup based right here in Oregon. We’ve been helping Defox develop and launch its Periscope Case, an innovative phone case which allows users to take photos and videos from the top of their phone.

True to its name, the Periscope Case uses a mirror alongside the phone’s built-in camera to operate just like a periscope on a submarine. By reflecting the image into the camera, the phone can be mounted or held flat while still being able to take photos and videos along its length.

The article explains that Defox’s founder, Trevor deVos, came up with the idea when he needed to investigate his crawl space, but understandably did not want to venture in himself because it was filled with spiders. He made the first prototype of the Periscope Case with molded clay, mounted his phone to an RC car, and streamed the video to himself on Facebook. Problem solved!

3D printing: affordable small-scale manufacturing

DeVos quickly realized that he wasn’t the only do-it-yourselfer or handyman who would be able to benefit from the ability to shoot photos and videos in tight spaces with his phone. Additionally, sports enthusiasts and parents might also be interested in what he called “a poor man’s GoPro.”

At the same time, the Periscope Case’s market did not have a guaranteed size, and deVos wanted a way to move forward with the product without risking a large investment or committing to a final design too early. 3D printing was an obvious choice, since it produces durable, high-quality plastic products but does not require the expensive tooling, molds, or setup time associated with injection molding or machining.

To that end, RapidMade worked with Defox to begin manufacturing its Periscope Cases in batches of just 10 to 25 units using the HP Multi Jet Fusion, which allowed a ramp up of initial sales while continuing to modify the design without a large initial investment. Because of this, Defox has been able to research the market and refine its product. Now, they plan to continue to expand their manufacturing operation, both with the Periscope Case and other products using the same knowledge and supply chain.

New business models for new manufacturing technologies

Products like Defox’s Periscope Case illustrate the unprecedented benefit that 3D printing can offer to small businesses or other low-volume productions with affordable, flexible manufacturing solutions. Because of their low initial investment, customizability, and high quality, 3D printed products allow businesses to offer competitive value under constraints that would make traditional manufacturing prohibitively expensive, opening up new opportunities in under-served markets. Innovators like Defox are at the forefront of exploring new business models using additive manufacturing, and we can’t wait to see what the future holds for them!

HP Multi Jet Fusion 3D Printing at BMW Group

The folks at 3DPrint.com recently reported that BMW Group used the HP Multi Jet Fusion to print their millionth 3D printed car part. According to the article, BMW Group has been using additive manufacturing technologies for the last 25 years. The number of 3D printed parts in their manufacturing operations has risen sharply, with an estimated 200,000 parts to be printed in 2018—a 42% increase since last year.

So what was the millionth part? A 3D printed window guide rail for the BMW i8 roadster. According to 3DPrint.com, the guide rail was developed in just five days and is part of the first wave of parts being printed by the Multi Jet Fusion for BMW. It’s far from the only part BMW produces using additive manufacturing, however. They also use SLS and other technologies to produce plastic and metal parts for many of their vehicles, including made-to-order custom parts for their customers. Per the article, Rolls-Royce, which is owned by BMW Group, currently uses 10 different 3D printed parts for their cars.

While many car manufacturers use additive manufacturing to produce tooling, BMW Group has been a pioneer in using 3D print technologies to create the parts themselves. They first started using 3D printers to make parts in 2010. In 2012, they began using SLS to manufacture parts for the Rolls-Royce Phantom. And it doesn’t look like they have any plans to slow down. This year, they built an entire Additive Manufacturing Campus, so keep an eye on more 3D printing innovations to come.

Here at RapidMade, we know firsthand how effective the HP Multi Jet Fusion is at manufacturing high-performance 3D printed parts faster and at less cost than any other 3D printer on the market. Still, it’s exciting to see world-class engineers like those at BMW Group taking advantage of such a promising technology.

If you’d like to see how Multi Jet Fusion printing or any of our manufacturing services could help your business, get started today by filling out our quote form. We’ll get back to you with a quote in 24 hours or less!