World's Smallest Sand Castle

Background

I was looking for some fun, clean, April Fools pranks when I found a printable joke about the worlds smallest sand castle, "carefully crafted by microscopic nanobots." What you really do is glue a tiny pinch of sand to the paper.

This might fool some gullible, elementary aged children, but in my line of work we can easily view objects on the micro and nanoscale. We have powerful optical microscopes, scanning electron microscopes, confocal microscopes, laser interferometry, etc. So I got thinking about what it would take to really build the world's smallest sand castle.

The Idea

I think it would be a fun project to actually build the world's smallest sand castle (if it hasn't been done already). To accomplish this I would build it from real grains of sand by stacking them one at a time like giant building blocks. Okay, they are actually tiny building blocks, but think about buildings that are made from huge granite blocks. I would treat each small grain as if it were a huge building block. That gives you a sense of scale of what I want to build.

There are many different types of sand, but the typical size distribution goes from 0.06mm to 2.0mm. To make building easier I would try to find a high purity silica sand with grains filtered towards the smaller end of the spectrum, around 0.10mm. I think the biggest problem with building on this small scale is that the building blocks won't be square. Unlike salt crystals, silica crystals take a much more random form and will be rounded on all sides. This means I'll need to be creative to get the grains to stick together. The most obvious answer would be to glue them in place.

The last, and I think most difficult / expensive, challenge to overcome is how to actually perform the building.  How do you move the sand grains into place and glue them there?! Really steady hands and lots of patience? I think not. I've done lots of work lately playing with servos, and motor controllers, but those just don't have micro-scale accuracy. After a little research I think I'll use micromanipulators. These are mechanical devices used mostly by biologists to work with individual cells under a microscope. If I can get my hands on one or two of these things then I might have a shot at a world record.

Progress

02/03/2015 -

Has it Been Done Before?

Using my Google-fu I checked for any prior attempts at my idea. The current claim to the world's smallest sand castle comes from Vik Muniz. He has taken an individual grain of sand and used a laser to etch a picture of a castle. I think this is awesome, and a clever twist on the idea of a sand castle. However, it does not qualify as a 3D structure build from multiple grains of sand.

I also found a few photos of small castles built with more traditional techniques by J.W. Gruber. He makes a tightly packed block of sand then carves out the castle. Probably the smallest freestanding examples with extensive detail.

Here is a gentleman who does micro-sculpting by hand between his heart beats. He could probably do it without using any extra equipment. His pace is a little slow, but that's exactly the attribute that makes him successful: Willard Wigan TED Talk

Looking For a Micromanipulator

• New on Amazon: $1,500
• Used Industrial: $150 - $500
• 3D Printed Low Res: $100

The 3D printed version actually gives me an affordable way to research the feasibility of this idea. As soon as I get the nozzle on my printer repaired I may dig into this.

03/31/2019 - I still want to do this one. It just seems unique and fun. I've had the 3D-printed micromanipulator and VR goggles on my desk for at least a year.

I've been stuck on the optics. I'm trying to maximize both the free working distance and the depth of focus around the optimal magnification level for medium sand grains (about 0.1 mm). If you've ever used a microscope, you may have noticed that everything looks flat or out of focus. This is because when you zoom in to high magnifications, only a thin section of material is in focus.

With my design, I've been trying to overcome this flatness and give a sense of depth and dimension by using stereo 3D microscopy. This has been done successfully by Gary Greenberg, but he looks like an academic gone commercial. I can't afford his equipment, and he doesn't publish the design since he's selling them for over $40,000 on Amazon. From his websites it looks like he's relying on Z-stacking to get full-depth 3D images. In other words, the camera automatically takes images at different focal depths, then a computer combines all the parts that are in-focus to create a neat looking picture. So it's not REALLY real-time, live 3D viewing.

That depth of focus is going to really make this project a challenge. My problem is that I don't have the money to just play around with expensive optics, and I don't know enough optics theory to design my system on paper to know exactly what to buy and how that translates to a workable system. I've gotten a rough idea by studying scopes for soldering electronic components, and I found DIY stereo microscope that I might try.

Or maybe I should build the end-effector first and try to find a lab with a standard stereomicroscope and see if a standard mag like 65 or 90 is sufficient for what I need. Then I'd feel okay dropping the $250-$2500 for a standard lab unit.

A Study of Adhesion Strength in 3D Printing

Background

I'm having terrible adhesion problems on my new 3D Printer. It's keeping me from making progress on other projects that rely on 3D printed parts. While researching a fix I discovered that this is a universal problem among hobbyists, and everyone has their own solution including glue mixtures, taping schemes, heated beds of varied temperatures, cleaning solutions, various print bed materials, calibration routines, etc. I understand that everyone has a slightly different build, and those builds will add variation. But I think that excuse is over-used because of the lack of usable data. The common theme seems to be people trying one thing after another until they find something that works. Very unscientific.

I really don't want to take a "shotgun" approach to this problem, but I don't really want to use my free time systematically designing and running experiments to collect the necessary scientific data. It would require a force gauge which costs around $100 for a decent unit, and I would rather burn that extra money on something more fun.

As an engineer I get this type of data from companies who are dedicated to performing experiments to collect data on heat capacities, enthalpies, transfer coefficients, etc. etc. etc. We just pay someone else to collect the data. I haven't found an entity in the 3D Printing world that has undertaken the science of all these little problems that hobbyists face.

The Idea

Since I'm losing my job in June 2015 I'll have some free time. I could probably dedicate myself to a systematic study of 3D Printing problems. I'd design and perform experiments on print adhesion using different substrates, temperatures, filaments, surface treatments, etc. Then I could publish and hopefully sell the information to pay for my time and the capitol required to perform the studies.

My big concern is how to distribute the content in a manner that will help pay for the time and capitol invested into the project. I'm a big believer in publishing this stuff for free, but there's so much work to be done I don't think I could afford to go unpaid for that long. Maybe I could get funding up front via KickStarter so I can reduce the risk of recovering a personal investment. That would also help reduce the risk of people just copying and redistributing the content. If it was paid for up front then I could just post the results for free. Otherwise I'd have to look into a distribution method to protect the copyright, like a website or cell phone app.

Progress

 11/10/14 - Just an idea so far. How do I gauge the potential interest from the community?

Build a 3D Printer

Intro

3D Printing is a manufacturing method in which a "printer" type machine is used to create objects.  Printers can get really fancy and expensive printing things like ceramics, metals and plastics. As a hobbyist I'll be focusing on Fused Deposition Modeling or FDM. This method pushes melted plastic out of a small nozzle and creates plastic objects layer by layer.

This page is just for me to store stuff about 3D printing. Honestly, most of my useful pages are stored in bookmarks on my browser, but the exceptional stuff I'll post here for others to reference.

Printers I Evaluated

• Prusa i3
• Rostock Mini Pro
• RichRap 3DR
• Kossel Mini
• DeltaPrintr
• PrintrBot Simple

What I Bought

I ended up buying a Rostock Mini Pro kit from 3DPrinterCzar. Happy Early Birthday!!! I could have sourced all the parts myself, but I want to spend time building and tinkering, not sourcing and purchasing. I also didn't document the build process, because many others have already done that (e.g. deltarap.org).

Things I Want to Print

• Cell phone grip for playing games
• Cell phone mount for game controller
• Toy gears for the kids (and me)
• Legos
• Construx
• Action Figures drawn by Lewis
• Hobby Boxes
• RPG Figures
• Modular Storage (jewelry, tackle, hardware, electronics, etc.)
• Headphone Stand
• Custom Sun Glasses
• Disposable Tweezers
• Car Rack Mounts (to carry wood for example)
• Parts for rubber-band guns.

Heated Bed

 The Rostock that I ordered does not come with a heated bed that would be required to print using ABS or nylon and other various materials. I perused various options for buying or building a heated bed. I'm going to either buy or make a round kapton tape heater. In the theme of DIY, reprap, etc I liked this post on using resistive wire. I think it might be cheaper to use an aluminum clad heater, but this one is easier for me to do. If I do it this way then I'll use thinner gauge resistance wire, but print a template for laying the wire. I'll put kapton tape over the template and lay the wire into the template grooves so it sticks to the tape. Then peel the template off and press the tape onto the bottom of the print table. It's all theoretical, of course, but I think I'll give it a try.

 Useful Links

• Jérémie FRANCOIS's 3D Printing Blog - He's got some good articles on printer settings, materials, improvements, etc.
•  RepRap.org
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Micro 3D Printer

While researching different 3D printers I found they all use stepper motors for positional control. It got me thinking what other technologies exist that could be used as replacements to improve cost, accuracy, etc. In my industry we use interferometers for nanometer-scale positioning. I wonder how this could be applied to 3D printing. I doubt it will be as cost effective as stepper motors, but it certainly will improve accuracy. Then I got wondering how small you could make a 3D printer. I haven't seen anyone compete for printing the smallest object yet. Well, if you count a FIB as a 3D printer then this doesn't really matter, but I'm still thinking objects observable with the human eye. It might be a fun way to show what the technology is capable of doing and possibly open up some new markets or applications. So for positioning control you could use simple, amateur interferometers. Maybe modify the kind used for amateur astronomy. There are other positioning technologies that might be better suited. This may also require a change in the actuators for improved accuracy.