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How 3D Printing is Disrupting the Making of Footwear

How 3D Printing is Disrupting the Making of Footwear

Footwear industry is a unique industry that demands extensive research for newer, tougher and light weight materials for manufacturing new and premium shoes. Big footwear brands like Adidas and Nike are taking 3D printing to the very edge by directly collaborating with 3D printing companies like EOS, Formlabs and 3D systems to develop performance, sports wear shoes.

Materials

Using right materials that suit the manufacturing requirement for the shoes is key. Elastic Polyurethane based materials and flexible TPU are the most preferred materials for manufacturing shoes. These materials are used to make shoe mid soles or the upper parts of the shoe.

Speed

It is important that the 3D printing process is also faster for mass production. Hence companies have also working closely towards achieving a faster printing rate. For example, Carbon, a 3D printer manufacturing company has come up with Digital Light Synthesis to cure photosensitive resins quicker.

Geometry

Being able to bear the load of the person and also being light in weight poses a design challenge. But with 3D printing, complex lattice structures can be manufactured. Adidas unveils Futurecraft 4D, which is the world’s first mass-produced 3D printed shoe. The shoe’s midsoles have a unique lattice structure that is light weight, durable and is completely resin printed.

Customization

3D printing helps the footwear and fashion designers to quickly generate concepts and evaluate them. Nike which is one of the top brands experimented by conducting a 3D printing workshop that allows customers to customize their shoes and then place the order. ECCO also announced that it is launching a similar system and it partnered with Dassault Systems for developing the tool that allows customers to choose their designs among pre-modeled combinations.

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An Overview of 3D Printed Metal Implants

An Overview of 3D Printed Metal Implants

In the days when 3D printing was not yet developed to meet medical standards, metal implants were produced using traditional manufacturing methods like casting and machining. This posed several problems, like having to visit the medical center to prepare the cast mold impressions on the patient’s body, waiting for the implants to be manufactured, and having to go through iterations till the required shape and fit is achieved on the patient. These approaches were not patient friendly and led to delayed surgeries and treatments, which could have aggravated the severity of the medical condition of the patient. But thanks to the developments and extensive research put into metal 3D printing technologies, it has paved a way to efficiently produce metal 3D printed implants that can be customized specifically for the patient. Let’s take a dive into the widely used metal 3D printing methods for additively printing metal implants, the processes involved, and the advantages each of them offers.

Geometry Creation in CAD

The prosthetic that has to be made is visualized and a CAD model is designed with the help of the anatomical data obtained from CT/MRI scan. There are CAD automation tools that enable the designers to create the complex lattice geometries and internal pores in the implant models that specifically suit the patient. Implants like knees, hips, shoulders, ankles, etc. need tiny internal pores on the surface to stimulate bone growth and naturally allow integration of the bone with the implant.

 

Lattice structures like these can be created with software aids like Genesis and nTopology.

Metal 3D Printing

Intricate surface pores and complex geometries that are not possible to make in traditional machining and casting can be produced in additive manufacturing methods which served as a breakthrough in orthopedic healthcare. 

DMLS (Direct Metal Laser Sintering) and EBM (Electron Beam Melting) are the methods widely used for making implants. DMLS uses a metal powder bed and a laser to selectively melt and fuse metal powder particles to form the part layer by layer. EMB also uses a powder bed, but instead of a laser, an electron beam is used to fuse the metal particles together layer by layer to build the part. A quick comparison between the two is given below.

 

 

DMLS

EBM

Hear Source

Laser Beam

Electron Beam

Minimum beam resolution

100 micrometers

180 micrometers

Environment

Inert Gas Filled (Argon)

Vacuum

Layer height

30 micrometers

90 micrometers

Materials

Titanium alloys are the best suited materials for making implants as titanium is corrosion resistant to bodily fluids and the oxide layer that forms on top of it prevents it from further corrosion. Another great advantage of titanium is its biocompatibility, which does not trigger any harm to living tissues.

Advantages of 3D Printed Metal implants

  • Ability to quickly produce the parts in time to treat the patient as soon as possible. 
  • Customization options to create the implant as per the patient anatomy, size and requirement

Applications

 

As shown in the picture above, implants are used in cranioplasty (treating defects in the cranium bones) and arthroplasty (replacement joints for knee, hip etc.)

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3D Printing for Electric Vehicles

3D Printing for Electric Vehicles

In a big move towards sustainability and carbon emission reduction, all big automobile companies and startups are focusing on producing electric vehicle variants and many governments have already set targets for production of electric vehicles and are rolling out various incentives to increase the share of electric vehicles on road. Design, development and manufacturing electric vehicles pose several challenges for many automakers and EV startups mainly due to the fact that there are several aspects of the electric vehicle that need to be addressed from the very scratch. Some of the manufacturing infrastructure that exists for manufacturing conventional automobiles becomes partially obsolete and requires modifications. As electric vehicles use electric motors and batteries for mobility, the engine and gearbox have to be replaced according to the electric vehicle design. We will look at 4 stages of electric vehicles and then elaborate on how 3D printing can aid in solving the challenges.

Design Stage

1. LightWeight Body Parts

Unlike the conventional ICE automobiles, electric vehicles entirely rely on batteries for mobility. Range (maximum distance that can be traveled once the battery is charged full) of the vehicle directly depends on the weight of the vehicle. For getting the maximum possible range for a given energy store, the weight should be as minimum as possible. This poses an additional challenge as retaining the strength of the part is also the key. For example, just reducing the part thickness to reduce weight also reduces the strength. Hence the geometry and topology has to be optimized against the loads acting on the component. This means the part has to undergo design and validation cycles. 3D Printing can help in a lot of ways to test and optimize the parts. After the part is optimized for weight, it can directly be printed with Metal 3D printers. Also, binder jetting 3D printing method has proven to produce metal parts that are 50% lighter than conventional methods.

General Motors used Autodesk Generative Design tool to reduce rear seat bracket weight by 40% and increase strength by 20%.

2. Chassis Configuration

Electric vehicles do not use an engine to drive and instead use electric motors. Hence the transmission and battery pack has to be placed and optimized to accommodate in as much smaller space as possible to make the vehicle light weight. So the chassis configurations have to be decided by using small-scale prototypes. 3D printing techniques like FDM can be used to quickly print scale models and assess the possibilities.

3. Fire Safe and Electricity Safe Enclosures

Batteries need to be protected against heat and fire, and as batteries themselves generate heat during discharge cycle, the enclosure has to dissipate that heat properly. So enclosures that are well ventilated with vent holes need to be manufactured. Such complex designs can easily be made with 3D Printing. Flame resistant and flame retardant materials like ULTEM 9085 are available for 3D printing.

Production Stage

1. Tooling for Metal parts

Parts like the steering knuckles, suspension mounting brackets, electric motor housings are typically produced with metal casting/forging/machining process. They are later CNC machined with specialized tools for surface finish and drilling fastening holes. Specialized cutting tools are required to reduce the number of tool passes and operations needed to get the geometry. For example, center drilling and chamfering can be combined with a special tool that does both at the same time. Such special tool bases can be produced with metal 3D printing and then cutting tool inserts made of carbide or cubic boron nitride can be fixed onto them.

Metal 3D Printed Cutting tool produced by Kennametal for machining electric vehicle motor housing.

2. Tooling for Sheet Metal Parts

Mass production of sheet metal parts would require stamping die tools. Conventionally the shape of the stamping dies is machined on 5-axis machining centers to make metal dies that last several thousand cycles. But for experimental purposes and form validation, FDM 3D printed tools made of ULTEM 9085 can be used that have proven to withstand pressures up to 70 MPa and can last 300 pressing cycles.

3. Tooling for Die Casting

Metal parts that are produced with pressure die casting would need metal dies that have complex geometries that have cooling channels. Such intricate geometries are achieved with inserts. Recently companies are exploring ways to 3D print the dies to achieve conformal cooling channels that reduce the cooling cycle times.

4. Tooling for Plastic Parts

Several interior parts of automobiles are made of plastic such as dashboards, instrument panel covers, brake handles etc. that are injection molded. Design, development and machining of complex injection mold tools takes several months of time and also involves costs. So, companies are exploring ways to make 3D printed injection molds that require minimum machining. This also saves a lot of design and development cost.

5. Jigs and Fixtures

Assembling various components together require special work holding aids that make the process smoother and reduce assembly time. Jigs and fixtures ensure worker safety and minimize hand movements to increase accuracy. 3D printing is a great cost effective way to make jigs and fixtures. And not only the manual handling aspect, but several robots that handle the parts in the factory would also need grippers that do a specific set of jobs. If a new vehicle model is being developed, all subsequent production line handling needs modifications. It is possible to 3D print the robotic grippers that saves time and costs. There are some ESD materials available for 3D printing that prevent buildup of static electricity on its surface, thus preventing damage of electronic components during assembly.

Aftermarket Stage

The OEM supplier industry often survives based on orders received from other automobile companies. It is possible that at a certain stage the production of a specific part is discontinued. To ensure seamless aftermarket services, companies are planning to change the ecosystem by investing in 3D printing companies that can produce spare parts for them. Although 3D printing is a slow process that cannot meet the mass production volumes, companies can benefit from the flexibility, lower costs and faster delivery times offered by 3D printing methods in the years to come. With digital printing and smart inventory models, the cost of investing in 3d printer machines saves inventory and stock keeping costs.

Direct 3D Printed Parts

While it is true that 3D printing is being used to aid in the processes of design, development and manufacturing of automobiles which also includes electric vehicles, directly 3D printing parts that go into the vehicle are not yet capable to meet full scale production demands and hence it remains feasible only to limited scale production runs. But in the beginning stage where market adoption and customer acquisition is the key, additive manufacturing and 3D printing are great ways to roll out models onto the road. Although the exact break even line between mass production versus additively producing parts is not yet clear, global auto giants like BMW and Volkswagen have proved that additive manufacturing can be used for producing up to 1,00,000 parts per year which is still a decent number given the current numbers of EV adoption in India. 3D printer companies like Stratasys, 3D Systems, EOS, and HP etc. are directly working to develop the technologies even further to increase build volumes and speed to try and meet the demands of mass production and to directly contribute to making 3D printing a mainstream manufacturing method.

 

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Applications of 3D Scanning in the Automotive Industry

Applications of 3D Scanning in the Automotive Industry

3D scanning is the process of capturing 3D geometric data of an object using a scanning device and developing that data into a digital copy for further analysis. Depending on the use case scenario, 3D data can be used for various purposes. Several 3D scanners and 3D data processing software have evolved to deliver high precision and accuracy down to 10 microns that have eventually found their way into almost all areas of the automobile sector right from design, production, inspection, and service to aftermarket support. In this article, we will look at some of the top applications of how 3D scanning is helping the automotive industry not only in manufacturing but also in the aftermarket.

Design

Automotive design and styling studios use clay modeling and digital sculpting tools for creating new car concept models. After creating the prototype clay model, it is scanned using a 3D scanner to create a digital model. The scanning software converts the raw point data into a suitable format that is supported by CAD software. Class-A surface design tools are then used for defining each surface of the CAD model accurately. Once the CAD design is complete, it serves as the blueprint for all downstream engineering and manufacturing processes.

Benchmarking and Reverse Engineering

Benchmarking is the process of analyzing the designs of other car models and car parts and arriving at the best possible combination in terms of the performance needed. There are companies that exclusively do these jobs of scanning and reverse engineering the parts of an entire car with the help of 3D scanners. Design teams can make use of these digital replicas to analyze, benchmark, perform virtual teardown and value engineering to enhance the existing designs and come up with better designs.

Restoration

If any automotive part is not available locally, it can be produced with 3D printing without the need for complex tooling. And to do so, 3D scanning can be utilized. Today’s 3D scanners are capable of producing accurate details of the part that allow for exact replication with 3D printing. And not just 3D printing, but even for small batch production methods such as casting and machining too would need the design details of the part. 3D scanning is a great way in such scenarios in the creation of CAD models.

Customization

Creating custom internal features that suit the style and personality of the customer is a new trend that has evolved around automotive enthusiasts and sporting events. The part that needs to be redesigned is first scanned with 3D scanning and using that as a template, design variations are made such as a new dashboard, rear spoilers, rooftop mounts, custom seats, etc. 

Inspection

With the availability of metrology-grade industrial 3D scanners, it is possible to scan a given part and compare the dimensions with a reference model. This has enabled companies to evaluate the precision and accuracy of outsourced components and then verify if they fit well in the car or not.

Quality Assurance

Although there are several contact-type quality inspection tools for checking the dimensional accuracy of the parts produced, they are not always suitable for verifying complex geometries that have curved surfaces. Hence there are dedicated 3D scanning tools from ScanTech that allow engineers to not only generate the scanned surfaces but can also give deviation reports and full-color plots from an original CAD file. The portability and speed of the scanners pose as a versatile alternative to coordinate measuring machines.

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What is Reverse Engineering and its Applications

What is Reverse Engineering and its Applications

Reverse Engineering, Back Engineering or Re Engineering refers to the process of understanding how an existing product is designed and developed and extracting the design details. Reverse Engineering involves understanding how each part functions, often including breaking down the product into its individual parts for further analysis and hence this process of tear down has become an integral part with reverse engineering. It has been termed as ’reverse’ because process is not going from design to production, rather arriving at the design from an already produced product. Reverse engineering is not only used in the development of new products but also to solve issues with existing products, and not limited to products but aircrafts, ships, heavy machinery, factory equipment and construction. With the evolution of technologies like 3D scanning and digital tools to reconstruct CAD models of physical systems, reverse engineering is helping engineers in many ways. Reverse Engineering encompasses all aspects of the product engineering but in this article we do not cover reverse engineering from software development and electronic hardware development perspective.

.Reverse Engineering Process

Applications of Reverse Engineering

1. Part Replacement

Parts wearing out and failing is a common problem in any industry and would require replacement. And if the machine is old it is difficult to contact the manufacturer for spare parts. Or it could also be a situation where the manufacturer no longer is in business. But with the help of a 3D scanner, the defective component can be scanned and the data can be used to build the CAD design model. Once the CAD design is ready the part can be produced using rapid prototyping for replacement.

2. Part Service and Repair

Machines need servicing and repairing which involve dismantling the sub-systems and looking for the defective part and then calling for replacement procedures. If the design documents are not available, reverse engineering can help to prepare the maintenance sequences for training and aiding the personnel on what processes and sequences to be followed in identifying the problem and replacing the part. For example if the clutch disc has to be replaced in a truck, all the sequence of how the drive shaft, transmission cover and couplings have to be removed to access the clutch can be documented with the help of reverse engineering. 

3. Failure Analysis

Examining a product by each component that makes it function can help to identify cause of failure and any potential issues that may have risen due to design flaws. Once they are identified, they can be eliminated with design modifications. For example, if an LCD display needs replacement frequently, failure analysis can help identify if any loose PCB wire connectors are causing the display glitches or if the heat sink for battery heat did not dissipate properly leading to electronic failure etc can be assessed. In another example, if any particular component has shown failure at the joints or bolt holes, reverse engineering can help to create the CAD data of the part and only the joining geometries can be modified or strengthened with ribs without having to design the whole part from scratch.

4. Parts Improvement

Companies perform reverse engineering on their competitor products to understand and improve. Not just observing the competitor products alone, but often improvement on previous versions is the key to retain the interest in customers. And the results from failure analysis will help to bring out new ideas for part improvement. 

5. Diagnosis and Problem Solving

Factors follow several processes to produce their end products. Reverse engineering can help understand the flow of each process and thus to establish a maintenance protocol. It can also enable for creating and documenting knowledge so that if anything goes wrong in the machinery and operations it becomes easy to deal with fixing the problem.

 

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Technologies That are Making Composite 3D Printing Possible

Technologies That are Making Composite 3D Printing Possible

Composite materials are lighter and stronger hence have high strength-to-weight ratio finding applications to replace traditional parts in automotive and aerospace industries. Composite materials have been in existence for a long time but they have been manufactured by means primarily in mass production setups.  Composite printing is still in the beginning phase of adoption that is restricted to industries but soon we will be seeing plenty of composite 3D printed parts replacing parts printed with conventional materials and experts predict that the market cap for composite 3D printing could reach $10 Billion by 2028, as it combines both the advantages of composites and rapidly producing parts that are tailored for highest strength while being extremely light in weight. Composites enable not just the high strength to weight ratio alone, but further developments enable for enhancing other properties like electrical conductivity, high temperature resistance, chemical resistance, flexibility and durability. Before going into the details of how they are printed, let’s have a look at little background on composites.

What are Composites?

As the name suggests, composite material has 2 constituents, the Matrix and the Reinforcement. Matrix is the base material that fills in the most portion of the geometry while reinforcement is a supplement whose job is to enhance the properties of the base matrix, primarily the strength. A point to note is that both matrix and reinforcement do not mix homogeneously (such as in alloys or blends) rather exist independently in the part geometry thus is the distinction between an alloy and a composite. Composites can be classified based on material of the matrix (polymer, metal or ceramic) and what form of reinforcement is given to it (particle, flake, fibres, laminates).

Types of 3D Printable Composites

So far companies have achieved to print nylon polymer based composites that are reinforced with fibres like carbon fibre, kevlar and glass fibres. And depending on how the fibre is embedded in the matrix, they are further classified as Continuous Fibre Composites and Chopped Fibre Composites. In Chopped Fibre Composite, the reinforcing fibre is chopped and mixed with the base matrix and printed as a single material. In Continuous Fibre Composite, the reinforcing fibre is laid as a continuous strand at desired locations using a separate print head. Parts printed in continuous fibre have significantly better properties than chopped fibre.

Technologies for printing Chopped Fibre composites:

Fused Deposition Modeling: Filaments made out of chopped fibre composites can be printed in Fused Deposition Modeling machines. However, the printer has to support specialized nozzles and print extrusion units so that nozzle abrasion does not take place and also the heating unit is capable of melting composites. Ultimaker has released its Red CC Print Core for S5 printer and has certified selected third party composite filaments that work with their printers. Markforged has also pioneered printing of Onyx (Proprietary composite of Nylon + chopped carbon fibre).

Selective Laser Sintering: Powders made out of chopped fibre composites can be printed with Selective Laser Sintering. EOS has released Nylon powder reinforced with glass beads that are printable with their SLS printers.

Technologies for printing Continuous Fibre composites:

This is an emerging area and companies like Markforged, Desktop Metal and Anisoprint have pioneered their own techniques that resemble a dual-mode Fused Deposition Printing to print continuous fibres of reinforcement materials with a separate print head alongside the primary print head that prints the matrix.  Markforged uses fibre in wire spool form calling it as Continuous Fibre Fabrication (CFF) while Desktop Metal uses reinforcement fibres in tape form calling it as Micro Automated Fiber Placement (μAFP). 

Image shows CFF printing in action on Markforged Printer. Black Matrix being a Nylon mased polymer while Amber coloured outline being Kevlar Fibres.

Image shows Markforged Proprietary Eiger software allows for optimal placement of fibres with specific
settings for added strength.

Parts printed in CFF can reach strengths of aluminum parts, thus offering an excellent alternative to replace aluminum parts that are made with traditional manufacturing methods.

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How SLS 3D Printing is solving challenges in Eyewear Industry

How SLS 3D Printing is solving challenges in Eyewear Industry

Eyewear industry is a unique industry posing several challenges that led to companies exploring new possibilities with 3D printing. From the customer’s perspective, there are 3 aspects: The need for newer designs and looks, the demand for customized eyewear solutions, and quality. From the manufacturers’ and retailers perspective there are again 3 aspects: the need for having to maintain stock of eyewear frames, managing the inventory, and ensuring quality and timely delivery. Let’s see how 3D printing is solving these challenges in each stage.

Technology

3D Printing is a generic term but the printing technology has to be capable of achieving top notch surface quality, strength, light in weight and aesthetic look to the frame. For prototyping purpose or for direct use, any 3D printing technology out of FDM, SLA, SLS can be used for making the frames but most companies are making use of Selective Laser Sintering (SLS) machines that fuse Nylon powders under a laser that offers reliability,  accuracy and speed. Marcus Marienfeld AG, a Swiss eyewear company has been using Nylon11 powder and Formlabs Fuse1 printers. Due to the large build volume of this printer, they were able to produce a series of batches for selected design models. Although SLS prints leave a matte rough finish on them, the company pioneered a proprietary post processing technique to give high quality surface finish to the frames after they are printed.

So far we have seen the frames getting 3D printed but it cannot be said that printing lenses as per the prescription is not possible and Luxexcel, a company that is working on lenses has patented the micro droplet technology to 3D print ophthalmic prescription lenses.

Design Freedom to evaluate newer models

3D printing has opened design freedom for both designers and modelers to innovate new models that look great. Once the concept is convincing enough, the relevant tooling can be developed for producing in mass scale. Marienfeld said it is leveraging the SLS printed tools to bend titanium frames saving them both development and manufacturing costs for steel tool dies. And innovation has helped to eliminate screws and have 3d printed hinges instead!

Selection Options for Customers

Companies like Hoet, Specsy and Monoqool are offering a new form of service where the customer can talk to the design experts and can get a new design that suits best for him/her or can select 3D printed models from a catalog. 3D scanning is used to obtain the shape of the face and then a suitable design is then developed. Then that frame is offered to be 3D printed in any of the company’s partnering facilities

Hybrid Designs

Companies are making hybrid designs possible where some areas of the frame are made out of Titanium, gold, platinum metals (that are used in conventional eyewear) and are joined with 3D printed structures made out of Nylon. This gives a new look and also reinforcing the frame while keeping it extremely light.

Cost Saving

This is a new where the companies are working with logistics and inventory management models where various 3d printing partners who can 3D print the designs for them are identified. Based on the location of the customer, the design is printed and delivered without having to maintain an inventory stock thus saving both transportation and stock keeping costs.

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How 3D Printing is Disrupting the Making of Footwear

How 3D Printing is Disrupting the Making of Footwear

Footwear industry is a unique industry that demands extensive research for newer, tougher and light weight materials for manufacturing new and premium shoes. Big footwear brands like Adidas and Nike are taking 3D printing to the very edge by directly collaborating with 3D printing companies like EOS, Formlabs and 3D systems to develop performance, sports wear shoes.

Materials

Using the right materials that suit for manufacturing the shoes is key. Elastic Polyurethane based materials and flexible TPU that are custom-developed for making shoe mid soles or the upper parts of the shoe are used.

Speed

It is important that the 3D printing process is also faster for mass production. Hence companies have also working closely towards achieving a faster printing rate. For example, Carbon, a 3D printer manufacturing company has come up with Digital Light Synthesis to cure photosensitive resins quicker.

Geometry

Being able to bear the load of the person and also being light in weight poses a design challenge. But with 3D printing, complex lattice structures can be manufactured. Adidas unveils Futurecraft 4D, which is the world’s first mass-produced 3D printed shoe. The shoe’s midsoles have a unique lattice structure that is light weight, durable and is completely resin printed.

Customization

3D printing helps the footwear and fashion designers to quickly generate concepts and evaluate them. Nike which is one of the top brands experimented by conducting a 3D printing workshop that allows customers to customize their shoes and then place the order. ECCO also announced that it is launching a similar system and it partnered with Dassault Systems for developing the tool that allows customers to choose their designs among pre-modeled combinations.

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The tides of 3D printing seem to trend upwards when it comes to Art of Surfing.

Over the past few years , 3D printing technology has been creating impacts across varied sectors.The waves created by 3D printing continue to rise and fall but when it comes to surfing and the art of surfing the waves seem to never subside.Surfing is a sport and a hobby that has been around for centuries, with people from all around the world, all walks of life, and of both sexes taking part, no matter how cold of a climate they live in. Surfboard manufacturers around the world have been experimenting with the design of surfboards and fins with the advent of 3D printing.

jigsurf10
Robotham with his Jigsurf

There is a guy named Robotham , who is currently a student majoring in Industrial Design at Victoria University in Wellington, New Zealand, he created a 48-piece surfboard made entirely from 3D printed components. Robotham began thinking about how he could create a surfboard that could collapse and fit into a duffle bag so he could more easily transport and carry it wherever he wanted to go. After contemplating various design ideas, such as a telescopic or folding surfboard, he finally came up with an idea for a jigsaw-like constructed version which he calls Jig-surf. After mocking up a a 1:5 scale design on Solidworks and then 3D printing it, he was able to pinpoint certain issues that would need to be corrected prior to printing out a full scaled version of his creation

jigsurf1-1024x342

In all, the surfboard consists of 48 jigsaw-like pieces, each of which took around 3-4 hours to print out. Robotham says that he also would print out multiple pieces on a single print bed, in a process that would take around 10-14 hours to complete. In all, the total print time needed to create this 5’9″ surfboard was around 6 full days.

Roy-Stuart-3D-Printed-Warp-Drive-Fin
Roy Stuart and his 3D Printed Warp Drive Fin

Prior to that, we watched as fellow New Zealand surfer Roy Stuart gained notoriety from the surfing community for his unique 3D printed Warp Drive fins.Roy Stuart started surfing when he was just four years old and he built his first surfboard in the garage using his grandfather’s tools when he was nine.Stuart went on to build his first surfboard fin when he was fifteen, and by 1994 he and his wife were building and selling a line of wooden surfboards.gull-wing-surfboard-fin-bumpy_grande

In October 2013, Stuart began offering the first 3D printed surfboard fin, and the rest is history.Stuart’s fins are 3D printed in poly-carbonate and they take the biology of the humpback whale and the microgrooves of shark skin as inspiration.

With his Warp Drive Fins the native New Zealander says fins like the Bumpy Leading Edge Foiled (BLEF) spitfire fin were once painstakingly hand foiled in wood, a process which took over 40 hours of work. Stuart says the process of creating a custom fin that could be sent anywhere in the world at short notice is simply not possible using traditional methods and glass and plastic materials.Stuart says 3D printing has enabled the creation of lightweight, honeycomb cored fins which are tabbed for use with “Futures” fin boxes and universal single fin boxes.Designed in Solidworks, the fins are printed vertically using the FDM process to make certain that when the fin flexes, the various layers undergo the least stress.

Now, for those who don’t have much experience riding upon the ocean waves, the fins of the surfboard might not seem to hold that much value, but those who are experienced surfers know that different fin designs can alter stability, control, and thus the overall performance of the surfboard.In New South Wales, Australia, researchers from the University of Wollongong have recently begun 3D printing surfboard fins that are tailored to serve the needs of the individual rider or the local surf forecast.Led by Professor Marc in het Panhuis, the Associate Dean of UOW’s Faculty of Science,Medicine and Health, the research team has already 3D printed a number of surfboard fins, and are currently testing their functionality upon the waves.

printed-surfboard-fins-8-1024x575
UOW professor Marc in het Panhuis and a surfboard with 3D printed fins.

Thus far, the University of Wollongong researchers have tracked more than 1,400 waves and 1,100 turns, which has enabled them to pinpoint which parts of the fin need improvement. Professor in het Panhuis and his team are already in talks with a handful of Australian surfboard manufacturers, and are looking to first introduce their 3D printed fins to the coastal city of Wollongong, and hopefully thereafter across the oceans of the world. With their 3D printed fins, Dr. in het Panhuis and his research team hope to improve the art of surfing for all levels of experience as well. By tailoring each fin for the needs of each individual surfer or surfboard, the University of Wollongong is looking to help these wave-riders conquer the ocean with their own style and preference.