FDM

3D Printed Food: A Sweet Idea

3D Printed Mesh Egg, work of Julian Sing (http://www.3dprintingpin.com/3d-printed-sugar-models-made-from-sugar/)

3D Printed Mesh Egg, work of Julian Sing (http://www.3dprintingpin.com/3d-printed-sugar-models-made-from-sugar/)

Any time I see an article about 3D printed food, I’m drawn to it… after 18 years with Nabisco, it’s a habit.  Lately, I’ve been speculating how the technology will change our approach to food processing, especially baked goods.  And despite my enthusiasm for additive manufacturing, I’m not sure the industry is going to widely adopt 3D printing – it took YEARS for them to abandon lard for soy bean oil.  Maybe to appreciate my skepticism, you have to understand:

1.    How baked goods are typically made

2.    Where most challenges occur in the process

Just like at home, the first processing step is mixing.  You take your ingredients (several ingredients - all of which have different handling requirements and product characteristics) and mix them together in a methodical way.  The methodology – and technology - differ based on what is being made. So, I can’t see a near-term solution to this challenge.  Other than automated delivery or continuous mixing, traditional manufacturing techniques are likely to remain dominant.

After mixing, you turn the dough into cookies or crackers.  Here’s the next challenge, cookie doughs and cracker doughs are generally very different and – yep - have different handling requirements and product characteristics.  Cracker doughs first have to be sheeted and layered to ensure the crackers are flaky.  Afterward, cutters form the crackers.  If they’re round, there will be excess dough but it is immediately reused.  Salt is then applied.  Cookie doughs are mostly soft and so are deposited or molded into shape – already efficient processes that generate little scrap if done right.  So if food processing is already efficient and generates little scrap, there’s less advantage to adopting additive manufacturing techniques.   

Next, the raw dough pieces are baked... typically by continuous baking, often on ovens the length of football fields with hundreds of top and bottom burners that are 5+ feet wide.  As the product travels through, it is baked, usually in 3 -7 minutes, and afterward, if needed, coated with toppings like oil.  The continuous nature of baking is also very efficient – if done correctly – and again, makes 3D printing less practical.  If it is an iced cookie then the coating is applied through extrusion in a manner somewhat similar to Fused Deposition Modeling, the warm icing is applied and quickly hardens as it cools.

Probably the biggest obstacle is existing infrastructure.  The largest food processors have millions committed to traditional manufacturing and are not likely to radically transition to additive manufacturing.  Yes, Hershey plans to 3D print custom chocolate designs and Contractor has “created a proof-of-concept printer that can print chocolate onto a cookie” but current chocolate processing is already an additive process:  The liquid is poured into a mold and hardens as it cools.  Where it differs is the resulting chocolate is a standard design and not customized.

But let’s consider how and when 3D printing might work. 

If you were observant, you picked up that cracker doughs are layered (laminated) before being cut, so one could print the doughs and produce a cracker ready to be baked, but not at the speed currently required of food processors.  

We could also theoretically laser sinter a cookie or cracker dry mix to form the product, but without oil or water, it probably wouldn’t taste great – and then there’s the flammability (explosiveness) of flour and sugar powders when subjected to sparks.  So that might be a problem…

Then there’s binder jetting.  This technique is actually being used by Julian Sing to 3D print objects in sugar:

According to Michael Franco “Combining his love of model making and baking, Sing modified a ZPrinter 310 Plus from 3D Systems to be able to produce creations out of sugar and water. The printouts aren't entirely edible yet because of a secret involved in the process that Sing wouldn't share, but they sure look good enough to eat.”  I found this observation very humorous for two reasons:  I know what’s typically used to bind 3D prints – and it is definitely NOT edible, and I can remember times during baking when sugar hardened into shapes on its own – and that was NOT very fun to deal with.

What about vat photopolymerization – well not the material - but the technique?  I suppose a process might be developed to expose layers of a liquid batter to light in a way to bake it, but again I can’t imagine it would taste very good or be efficient enough.

So why even consider these approaches?  Well space limitations might be one reason.  It certainly is a consideration in NASA funding Contractor’s work.  The schematic shown actually reminds me of existing food processing equipment – large holding tanks of ingredients from which the raw materials are drawn to be mixed or deposited.  As I mentioned, commercial ovens can span hundreds of feet and house as many burners.  Coming up with a process that could handle baking on the same scale might be appealing.

 But baking is only half the battle.  Once the product is made, it still has to be packaged - which can be a 2D printed nightmare... but that's another story altogether.

RapidMade to Print 3D Prosthetic Hand

The Engineering and Physical Sciences Research Council's Hi Tech Hand (http://phys.org/news/2013-10-future-d.html#nRlv)

The Engineering and Physical Sciences Research Council's Hi Tech Hand (http://phys.org/news/2013-10-future-d.html#nRlv)

In the field of 3D printing, medical advances have arguably received the most press, with good reason - 3D printed prosthesis are changing lives.  The London Science Museum is now featuring an exhibition that highlights one great example, a 3D prosthetic arm designed and manufactured by the Engineering and Physical Sciences Research Council's Centre for Innovative Manufacturing in Additive Manufacturing.  This prototype features "customised prosthetics with electronic moving parts and nerve endings, created by the research group at the University of Nottingham."

Unfortunately, the cost of high tech prosthesis like this is a serious drawback , especially when children are involved.  Kids need a medical device that won't cost an ar - well you know  the expression - their changing bodies require a less expensive alternative that can be replaced as needed to accommodate growth.

Version of McCarthy's Robo Hand RapidMade is Evaluating (http://laughingsquid.com/dad-makes-a-low-cost-3d-printed-prosthetic-hand-for-his-son/)

Version of McCarthy's Robo Hand RapidMade is Evaluating (http://laughingsquid.com/dad-makes-a-low-cost-3d-printed-prosthetic-hand-for-his-son/)

RapidMade is very excited to be partnering with a 13-year-old Oregonian who has a congenital amputation to customize, print and fit an inexpensive hand for him to evaluate.  Alex and his mom, Lori, visited us earlier in April to discuss the project and provide his measurements. 3D printing will allow us to size the prosthetic to match his hand instead of a "one size fits all" device. David, our engineer, has already begun printing parts and assessing design features. RapidMade hopes to make plastic prosthetic hands out of ABS plastic using fused deposition modelling (FDM) and Nylon using Selective Laser sintering (SLS) in order to better meet patients' specific needs for price and quality.   

We are grateful to Paul McCarthy who designed and shared the original version we are evaluating.  He and other designers have made their work available for free through open sourcing to drive down costs.  As 3D users already know, it is often the product design phase that is the most costly and time consuming, so to have a ready-to-print CAD file is an enormous benefit.

If this trial is successful, we hope to become part of a network that provides low-cost prosthesis to others who are similarly challenged.  Stay tuned for updates on our progress...