Get the Freedom to Redesign

Direct digital manufacturing (DDM) can benefit nearly every discipline within a manufacturing organization, and sometimes changes fundamental business processes. In this series of white papers, the unrecognized benefits of DDM will be disclosed to reveal the huge potential that the process offers.

In Part 1: Freedom to Redesign, you'll learn how you can redesign or alter products while in production.

To read the entire White Paper, click here.

Streamline Manufacturing with Fused Deposition Modeling (FDM)

All traditional manufacturing processes involve substantial investment of labor, time and money for toolpath creation, fixtures, tooling, molds and machinery. For example, a single injection mold can cost $75,000 or more and take anywhere from 8 to 16 weeks to manufacture. FDM has no tooling costs and the waiting period for the first production parts may amount to only a few hours.

This not only minimizes new-product startup investment, but can translate to better cash flow, improved profit and decreased debt for a company. Lowering the initial investment also opens the door to more product introductions.

To read the whole White Paper, click here.

FDM moves mountains for Chipotle

Get a behind-the-scenes look at how FDM 3D printing helped create Chipotle’s popular Back to the Start animated short film.




Fast-forward one minute into the movie to hear Bob Thorne, special effects supervisor at Artem Ltd., explain how his team shaved almost a week off a tight production timeline by using the Dimension 3D Printers to create just one character.

There is no limit to the end use of 3D printed parts.

To see how RedEye Australasia can help you with your next project call 1300 559 454.

To see the full flim click on the link below:

FDM prints an entire coffee table in one piece

In a recent article on imaterialise, a FDM printed modular coffee table was featured.

The Module, designed by celebrated designers WertelOberfell–Platform is printed in one piece on a Stratasys FDM (Fused Deposition Modeling) Maxum machine.

The coffee table is based on fractal growth patterns in trees and designed specifically to minimize waste. Individual Module coffee tables can be intertwined in order to get just the size of table you need.

To watch the build click on the link below.



The machine used in the video is the Stratasys FDM Maxum, one of the largest 3D printers in existence with a build volume of 600 x 500 x 600 mm. Redeye Australasia has a Maxum on the premises and can make large scale prototypes in a single piece within Australia, reducing waiting time for parts to a maximum of a few days.

The Stratasys 900MC in RedEye's American Build Centre is capable of building prototypes as large as 914 x 610 x 914 mm and can supply them direct to Australia through the Australasian Build Centre. See it in action below.



Producing prototypes with a high degree of dimensional accuracy, FDM is becoming increasingly popular for aerospace, automotive as well as art and other creative prototyping. For an instant quote visit http://www.redeyeondemand.com.au/.

Helping Hand for NASA

Mockup Helps Prepare Astronauts to Use Dexterous Robot on International Space Station

“The mockup has made it much easier for the crew to
train and prepare to utilize
R2.”
— Gina Young, Project Manager, Wyle

Wyle is a leading provider of high-tech science, aerospace engineering and information technology services to the federal government on long-term outsourcing contracts. Wyle’s Integrated Science and Engineering Group in Houston helped the National Aeronautics and Space Administration (NASA) prepare the Robonaut 2 (R2) dexterous (pictured right).

While most current space robotic systems, such as robotic arms and exploration rovers, are designed to move large objects, R2’s tasks require more dexterity. Its mission is to work alongside astronauts, taking over repetitive and dangerous tasks. Its form factor and dexterity are designed such that R2 can use the same space tools and work in environments suited to astronauts.

One of Wyle’s responsibilities under this contract was building a one-to-one scale high-fidelity mockup of R2 (pictured right) for use in the simulation of potential missions. The exterior of the mockup had to duplicate the geometry and appearance of the actual R2. The limbs of the mockup had to be easily moved into the same positions as the real robot. And, the mockup had to withstand rough handling that it might receive during simulation and training

“The geometry is very complex and we were under time constraints to produce the mockup,” said Robert Stevenson, mechanical designer for Wyle. The parts have so many compound contours that it would have been very difficult to hold them during finish machining. One consequence is that they would have had to be thicker than on the real R2 which would have added to the weight of the mockup. The estimated delivery time for conventional machining for the mockup was 8 months and the cost was $180,000.

“RedEye On Demand was a good fit for Wyle because of FDM’s ability to create complex geometries,” said Jeffrey Gangel, RedEye On Demand Account Manager. “FDM also provides the high level of accuracy needed to ensure that the many pieces required to build the mockup fit together during assembly. Finally, with the largest installed base of FDM machines and the largest inventory of FDM materials in the world, RedEye On Demand was able to meet the tight timeline for the project.”

“Our manufacturing lead had used RedEye On Demand digital manufacturing services in a previous job and had good results,” Stevenson said. “I sent CAD models to RedEye for quotation and evaluated the mechanical properties of the Fused Deposition Modeling (FDM) materials on their web site. The ABS material met our strength and durability requirements. RedEye was also very helpful in educating me in what I needed to do to get our CAD models ready for digital manufacturing.” Fused Deposition Modeling is an additive manufacturing process that builds plastic parts layer by layer, using data from CAD files.

It took only two weeks and cost $36,000 for RedEye to make all of the parts required for the mockup. The interior of the mockup is made from square tubing to provide strength. The mockup is positioned by tension in its joints like a mannequin.

“NASA was very happy with the mockup,” said Gina Young, Project Manager for Wyle. “They liked the fact that it was produced on schedule, is light compared to the original and is strong enough to withstand the large amount of handling it has received. The feedback we received is that the mockup has made it much easier for the crew to train and prepare to utilize the R2.”

The R2 flew to the ISS in February on the Space Shuttle Discovery’s last flight. Initially, R2 will be deployed on a fixed pedestal inside the ISS for operational testing. Next steps include adding a leg for climbing through the corridors of the ISS and further upgrades to go outside in the vacuum of space.

Free Webinar: Additive Manufacturing

Thermoplastics: A Solid Choice For 3D Printing

When designing a new product, engineers can best predict its end performance by prototyping with a material as similar to it as possible. Fused Deposition Modeling (FDM) thermoplastics use the same types of raw materials found in injection molding - and that’s why 3D printing is a wise choice. You’ll learn the unique properties of each thermoplastic and find out how these aspects can help you choose the right material. Join us as we introduce nine FDM materials and the characteristics that make them ideal for everything from rapid prototyping to low-volume manufacturing.

Presented By: Fred Fisher, Director Business Development, Stratasys, Inc.

What you will learn:
• What thermoplastic is the best choice for your application
• How additive manufacturing technology works
• What makes each FDM thermoplastic unique

Who should attend:
• Design Engineers
• Product Designers
• Manufacturing Engineers
• Inventors/Entrepreneurs
• Technology Educators

About Additive Manufacturing Technologies:
Additive manufacturing technologies are also commonly known as "Rapid Prototyping" or "3D Printing" as well as other names. And, although they are still being used by design engineers for concept modeling and prototyping, that’s not all. Manufacturing engineers are now employing these technologies for various applications such as jigs, fixtures, check gauges, and even as a bridge-to-tooling and low-volume end-use parts.

To view the free 30 minute Webinar click here.

Digital Manufacturing of Vacuum Forming Tools

Vacuum forming tools are a perfect application for Fused Deposition Modeling (FDM) technology. FDM has the unique capability of creating sparse fills that allow for a vacuum to be pulled through the part. Because of this built in porosity, the benefit for vacuum forming is that it eliminates the need for vacuum holes; the small vents in the tool that are normally created as secondary operation.

The other added benefit of sparse fills is build speed. And since thermoform tools are simpler in shape, not requiring any support, we can often turn these around in a day; Build on the day of the order, and ready to ship the next day.

Read on to find out how one RedEye customer was able to make the statement; "High quality prototype molds for custom thermoform packaging made 60% faster."

Prototyping Vacuum Forming Tools Quickly

Thermoforming is a collection of manufacturing methods that heat and form sheets of extruded plastic. Thermoforming processes include: drape, vacuum and pressure forming. Today, packaging is the leading application for vacuum forming. Excitingly, consumers see it everywhere from the plastic coffee lid on their morning cup of java to the clear plastic box their sandwich at lunch was delivered in. And, although thermoforming is most often used when manufacturing packaging items, the cost and time saving advantages are realized in a broad spectrum of products in an equally diverse range of industries.

Founded in 1993, the LINDAR Corporation stands on principles of innovation and resourcefulness. This plastics thermoforming company proudly serves customers in food packaging, paint sundry, medical and custom OEM markets. They offer a broad range of services including: product/tool design, high capacity product manufacturing, secondary operations, fabricating and assembly.

Upon recommendation by one of their best customers, LINDAR turned to RedEye On Demand to create quick, cost effective thermoform packaging prototypes. Find out how the team at RedEye saved them time and cut costs while delivering a high quality tool.

The Challenge

Doing more in a shorter period of time is something many businesses are faced with today. In order to keep their competitive edge and satisfy customers, LINDAR needed to reduce turnaround time of their thermoform prototypes. Additionally, they were neither satisfied with the end product or the level of service other agencies had provided.

LINDAR was excited to try RedEye's fused deposition modeling (FDM) technology for creating new packaging thermoform prototypes because the LINDAR team had tried Selective Laser Sintering (SLS) prototypes in the past, but they were brittle. "Ninety percent of our packaging projects require the use of hinges. RedEye's FDM technology allows us to create functional thermoform molds where other technologies fail," says the LINDAR team.

Another advantage of using RedEye's technology is the tools created are inherently porous, which is beneficial when vacuum forming because it can eliminate the need for vacuum holes (small vents in the tool). This unique property, a result of modified build parameters, is essential to thermoform a prototype part with good detail because all air must be removed during the forming cycle. If air becomes trapped (in corners for example), between the sheet stock and the tool surface the part is not formed correctly. The quantity and placement of the vents directly affect the quality of the formed part. Vent placement also affects the cycle time of the forming process. At RedEye, this porosity is designed into the rapid prototype, eliminating the need to locate and drill vent holes completely. RedEye tools offer excellent feature detail and fast vacuum cycles while eliminating the labor and time related to drilling vents.

In addition to producing a quality thermoforming tool, service providers need to complete design revisions and form parts in just a few days. Ultimately, they needed a service provider that could react in timeframes that are continually compressed. The LINDAR team says, "Our customers want to have concepts designed and thermoformed for review as fast as possible."

So, when one of their best customers requested RedEye service they agreed to give it a try.

The Solution

The LINDAR Corporation was able to offer their customer an innovative solution that was appropriate for their company and its objectives. "By using dEye, we have reduced our thermoform prototyping time by 60%," stated the LINDAR team.

Applying the technology at RedEye to the creation of vacuum forming tools offers many advantages: eliminating the time and labor required of machined tools - CAM programming, set-up and operation, as well as eliminating vacuum hole drilling. RedEye expedites the vacuum forming process while decreasing costs and time constraints.

The technology offered at RedEye has streamlined LINDAR's rapid tooling process. Combining the advantages of the 3D CAD and FDM technology, vacuum forming can be completed quickly, efficiently and cost effectively.

"RedEye On Demand exceeded our expectations without exception. We are happy to have chosen RedEye as our digital manufacturer of thermoform prototypes," says the LINDAR team. As a result, LINDAR will continue to use RedEye for quality thermoform prototypes.

When you need prototype thermoform molds quickly, turn to RedEye On Demand.

Read more RedEye Case Studies

3D printing critical in MINI World Rally Championship

Stratasys recently announced that its Dimension 3D printers and Fortus Production 3D Printers played a critical role in the development of the new MINI John Cooper Works World Rally Car (WRC).

The MINI Cooper WRC Team used the additive manufacturing machines to create a full-scale mock-up of the vehicle directly from the CAD (computer aided design) files, and it used the technology extensively on other assemblies and components of the vehicle.

The MINI WRC Team relied heavily on 3D printing throughout the car’s two-year development cycle. To design the test car, engineers used Stratasys FDM 3D Printing technology to create large parts of the engine bay, gearbox, steering assembly, vehicle interior and even engine components, such as intake valves. In addition to prototyping parts for the test track, the MINI WRC Team even produced some end-use parts for the finished car. One of the most visible of these is the ergonomically styled gearshift display and control panel, which is mounted on the steering column.

The development of the car, which will be featured in this year’s World Rally Championship, has impressed upon MINI WRC Team the importance of 3D printing in saving time, reducing tooling costs and enabling more design freedom of complex geometric parts.

“We would find it nearly impossible to build another car without using FDM technology,” said Paul Doe, chief design engineer. “We would never have dreamt of building the parts we did without the Stratasys machines. Using composite parts would have cost up to three to five times more.”

“MINI WRC Team’s use of FDM technology to develop a race-worthy car for WRC demonstrates that it’s both efficient and cost effective,” said Tim Heller, managing director of Stratasys Europe. “It’s nice to be considered an indispensable part of the prestigious team’s operation.”

MINI WRC Team used Stratasys Dimension 1200es 3D Printers and Fortus 400mc Production 3D Printers with polycarbonate and ABS materials.

MINI WRC Team Details

The MINI WRC Team made its debut in the FIA World Rally Championship in Rally Italy, Sardinia in May and for 2011 will be competing in just six European rallies with two MINI John Cooper Works WRCS. This is ahead of a full assault taking in all rounds of the championship in 2012.

MINI has a great rallying heritage and so for its two cars the team has chosen the numbers 37 and 52, which were carried by the cars winning the Monte Carlo Rally in the sixties.

Driving number 37 is Spain’s Dani Sordi with his co-driver being fellow Spaniard Carlos del Barrio.

Kris Meeke from Northern Ireland is driving number 52, and his co-driver is Paul Nagle from Southern Ireland.

This programme was initially announced last July, but even before then a lot of development had been done by MINI’s partner in this project Prodrive, one of the most experienced and respected operations in rallying. This UK based company from Banbury has no less than six World Rally Championship titles to its name. It was founded by team principal David Richards, who was himself a very successful rally co-driver.

“MINI powered by BMW Motorsport”: The heart of the MINI John Cooper Works WRC is the 1.6-litre, four-cylinder Di turbo engine, which is also available in the MINI production models.

The production engine was further developed by BMW Motorsport for the use in various categories according to FIA Super 2000 regulations. The power transmission takes place via an Xtrac 6-speed, sequential gearbox.

For its outings on the rally stages, the MINI Countryman chassis has been fitted with a roll cage developed by Prodrive, which exceeds the strict safety requirements of the International Automobile Federation (FIA).

Stratasys Inc. is a maker of additive manufacturing machines for prototyping and producing plastic parts. The company markets under the brands Fortus 3D Production Systems and Dimension 3D Printers. The company also operates RedEye On Demand, a digital manufacturing service for prototypes and production parts. According to Wohlers Report 2010, Stratasys supplied more additive manufacturing systems in 2009 than any other manufacturer, making it the unit market leader for the eighth consecutive year. Stratasys patented and owns the process known as FDM.® The process creates functional prototypes and manufactured goods directly from any 3D CAD program, using high-performance industrial thermoplastics. The company holds more than 285 granted or pending additive manufacturing patents globally. Stratasys products are used in the aerospace, defense, automotive, medical, business & industrial equipment, education, architecture, and consumer-product industries. Online at: http://www.stratasys.com/

FDM Technology is a trademark, and FDM, Stratasys, Fortus, Dimension and RedEye are registered trademarks of Stratasys Inc.

The FDM Tooling Alternative

The following events, although fictional, are very real problems in companies with low volume product needs.

Design Engineer (DE): " I just spoke with our tooling vendor and they are quoting us $15,000 just for the tool and the lead time is 4 weeks."

Engineering Manager (EM): Gets out his calculator. "We only need 50 parts, that's $300 per part not including their molding costs. We need these out in the field next week if possible. What's with the long lead time?"

DE: "Remember we designed in some complex features because it needs to fit with other components. Redesigning this will take another week minimum and we might have to create multiple parts to make this work, costing more to get it tooled."

EM: "What about those FDM rapid prototype parts we had built in a couple of days and tested last month? They withstood our testing requirements and as I recall they had some fairly complex features as well. Do you think using FDM would work for these parts in the field?"

DE: "You know what, this might be the perfect application for this part, I'll go find out what 3D printing service she used for those prototypes."

Sometime in the near future .......

The design engineer gave it shot and had a first article part delivered overnight for validation. The part worked great, so the rest of the 50 parts were ordered. The 3D printing service provider was able to build the parts over the weekend and had them delivered and on the doorstep by Tuesday, ready for assembly.

The engineers were treated like heroes for their ingenuity in getting the products into the field faster than ever before.

EM: "Using FDM as an alternative to tooling is our best secret weapon yet!"

Lesson Learned: Always have an alternative manufacturing method like FDM that can fit your budget and time. FDM IS an alternative to tooling and outsourcing can provide yet another vehicle to getting parts in your hands fast. For more details, visit RedEyeOnDemand.

Written by Tim Thellin from Stratasys Inc

Make Fiber Molds 80% Faster with a 3D Printer

Molded fiber packaging is an ideal choice because it's eco-friendly and sustainable. It's produced from old newsprint, corrugated boxes and a variety of other plant fibers making it 100% recyclable and biodegradable. Unfortunately, waiting three to four weeks for a machined mold might be a deal breaker.

With RedEye Australasia's FDM technology, you can produce a fiber mold in just a few hours. FDM technology automates and accelerates mold production by replacing the design, machining and screening processes of traditional mold building.

Download the application guide to find out how you can make paper pulp molds 80% faster with a 3d printer.

We Are ISO 9001 Certified!

If you outsource rapid prototyping and low-volume manufacturing, you know that trust is key. That’s why we’re thrilled to announce that we’ve received ISO 9001 Certification.

ISO 9001:2008 is based on eight quality management principles: customer focus, leadership, involvement of people, process approach, system approach to management, continual improvement, fact-based decision making and mutually beneficial supplier relationships.

With new ISO standards in place, we look forward to exceeding your needs.

Urbee - an additive fabricated car!

"FDM technology made it easy and efficient to make design changes along the way."
- Jim Kor, President and Senior Designer, KOR EcoLogic

Caring for the environment

"We should want to own and drive a clean, energy-efficient car," said Jim Kor, president and senior designer for the Winnipeg-based engineering group of KOR EcoLogic. His passion for the environment led him to design the principles of sustainability into a new car code-named Urbee and created with the 3D printing capabilities of Stratasys. The two-passenger Urbee, which stands for Urban electric with ethanol as backup, was designed to use the least energy possible. It is capable of reaching more than 200 mpg on the highway and 100 mpg in the city. And now, it is the first prototype car ever to have its entire body printed with an additive process.

When KOR leaders decided to create the world's most fuel-efficient and environmentally friendly vehicle, their goal was "to design a practical, roadworthy car that runs solely on renewable energy, is environmentally responsible and has universal appeal," Kor said. He hopes it will find a global market some day. Kor wanted to make Urbee aerodynamic and as "green" as possible throughout the design and manufacturing processes.

Initially, Kor and his team made half of a model of the car out of clay at 60 percent scale. By holding a mirror to the half, they could see what a whole model would look like without having to make the entire car. "A clay model has a reality that can't be denied," he said. "We can add and remove material and live with it on a daily basis. The downside is that it takes up to three months to make."

Next, the team had the model scanned into a computer to test its aerodynamic properties. They wanted to achieve certain goals or their computer simulations would be off, and the whole car would "unravel," said Kor. One very important statistic was the coefficient of drag (Cd), which they wanted to be 0.15 or less. By comparison, the Prius is 0.26. The computer model showed the Urbee's Cd to be 0.149. "This was amazing," said Kor. "It gave us the confidence to go ahead."

There was just one little problem. "We had everything in the computer but no way out," said Kor. He and his team knew traditional manufacturing methods would not provide the results they were looking for, so they explored other options.

One option was building the prototype body panels using fiber-reinforced polymer (FRP) or fiberglass. This would involve building a 1:1 scale plug for each of the body panels, first creating a strong framework of wood or MDF and covering it with dense foam that could be hand-carved into shape. Alternatively, the plug could be carved using a CNC milling machine to produce a more precise surface.

Then a mold would have to be made and layers of fiberglass and resin placed onto the surface until it maintained its shape. Once the part was cured, the component would be separated from the mold. "This is a long, labor-intensive process," said Blaine McFarlane, one of KOR's engineers. He estimated building all of the body panels from FRP would have taken 8 to 10 months of steady work for two people. Using CNC machines would have cut the time, but still taken three months.

"A fiberglass body would have taken a long time," agreed Kor. "In addition, we would have had to deal with draft, or the ability of the part to come out of the mold."

The solution: Printing a car

About the same time, one of KOR's industrial designers, Terry Halajko, sent Jim Kor an e-mail with a link to Stratasys. "Look at the size of the parts they can make!" he wrote. It seemed the team had found its solution. Conversations with Stratasys executives led Kor to believe that all exterior components could be created using Dimension 3D Printers and Fortus 3D Production Systems at RedEye on Demand.

Kor and his colleagues transformed the scanned computer model of the car into 10 logical body panels, first creating a 1/6th scale model to verify the exact fit of all the individual parts. This gave the team the confidence that the large panels would be trouble-free.

Together with Stratasys, the team selected ABS as the material of choice and began to build the car. Several major body panels were built within weeks of receiving the go-ahead. The full-scale door and side panels were completed first. "These were big panels," said Kor. "The parts fit together perfectly." The remaining body panels are currently being built by Stratasys.

"Just to make the first car was quite an achievement," said Kor. "With our second prototype, we will design to the Stratasys printer capabilities. We want to exploit the full capacity of the machines." That means designing both the inside and outside of the car. It also means putting plastic only where it is needed.

Kor likes to compare the fender of a future Urbee with a bird bone. "If you look at a cross section of a bird bone, you'll see that there is bone only where the bird needs strength," he said. "The bone looks like chaotic webbing. FDM is the only process that can replicate a bird bone." This will be important when building extremely light, yet strong, pieces, such as the Urbee's fender.

Currently, fenders are made to be a constant thickness, but much of the material is unnecessary, according to Kor. It only adds to the car's inefficiency and environmental waste. "Stratasys can build a fender and place the plastic exactly where it is needed," he said. "That is just so powerful, it's unbelievable. It is good for the environment, it reduces cost, and it doesn’t sacrifice safety. We simply don't need to put material where we don’t need it."

"FDM technology made it easy and efficient to make design changes in the Urbee along the way," said Kor. "It also helped us meet our environmental goals by eliminating tooling, machining and handwork. If you can get to a pilot run without any tooling, you have advantages." Currently, the Urbee is largely self-funded, but KOR's team hopes to raise money to build a second prototype. Once the money has been raised, Kor estimates it will take one year to build the next Urbee.

Kor marveled at the speed of 3D printing. "To have body parts that take days or weeks to make is pretty fast," he said. "Other methods are months away."

Kor said he feels a responsibility to initiate positive change by creating a vehicle that uses the least energy possible. "If we have the car model in the computer anyway, then from the designer's perspective, the 3D printed body is quite effortless," he said. "One just sends files, waits a bit, and…POOF…there are the body panels. No other process can really compare with that."

How Did FDM Compare to Traditional Prototyping Methods for KOR EcoLogic?

With FDM
Cost Affordable
Design Easy to make design adjustments
Time A few weeks

Using FRP or fiberglass
Cost Expensive labor
Design Each new design would require a new mold
Time Up to 10 months for two people

Learn about Direct Digital Manufacturing

The use of additive manufacturing processes is what differentiates direct digital manufacturing (DDM) from conventional manufacturing methods, and it is from these technologies that unique advantages and opportunities arise. Direct from 3D digital data, a component is manufactured - layer-by-layer - without machining, molding or casting.

Presentations are viewable in 4 separate sections:

•Part 1: What is Direct Digital Manufacturing (DDM)?

•Part 2: DDM - Advantages and Considerations

•Part 3: How to Identify Potential DDM Opportunities

•Part 4: How Companies are Using DDM

WHAT YOU WILL LEARN

•What direct digital manufacturing is

•6 major benefits of using direct digital manufacturing

•5 common traits of successful DDM implementations

•4 successful examples of DDM

WHO SHOULD WATCH:

•Manufacturing Engineers

•Operations Manager

•Design Engineers

•Tooling Designers

To view webinars, click here.

Make it fast with Thermoform Molds

Thermoforming is a collection of manufacturing methods that includes: drape, vacuum and pressure forming.

Today, packaging is the leading application for vacuum forming. Consumers see it everywhere from plastic coffee lids to the packaging of toys and their favorite electronic gadgets.

Find out how RedEye On Demand is creating high quality prototype molds for custom thermoform packaging -- 60% faster.

To read case study click here