ENDER 3D printer Archives - Perfect 3D Printing Filament

I always enjoy a good 3D printed DIY project, whether it’s truly helpful or just for fun. These projects are even cooler when you add Legos into the mix, like Reddit user DIY_Maxwell did. He posted about his work using 3D printing, Arduino, Raspberry Pi, and Lego bricks to make an open source, motorized microscope. But, the microscope itself is not fully 3D printed – instead, the body was built with Lego bricks and some 3D printed components. What makes this project more awesome is the stop motion-style video he made showing the various parts of the project and how they all fit together to make a working microscope.

BUILD YOUR OWN MOTORIZED MICROSCOPE using 3D-printing, Lego bricks, Arduino and Raspberry Pi… all design files, source codes and detailed instructions are provided open-source. from r/3Dprinting

“I wanted to have a modular microscope, something I can easily modify for transmitted-light, reflected-light, cross-section, etc. My early prototypes did not have Legos, as I started making my own interlocking pieces, I realized that I was in fact printing lego-like designs, I thought buying legos would be less of an effort,” he wrote on Reddit when asked why he didn’t 3D print all the parts. “Then I found out about these “sliding” lego pieces, which are very precise for linear actuators. The other advantage is that, if I want to change the height of the camera let’s say, I simply add more bricks, it’s convenient.”

DIY_maxwell used FreeCAD to design the 3D printed microscope parts, which were fabricated on an Ender 3 system. All of the source codes and design files have been provided open source on GitHub, along with detailed step-by-step instructions on how to make your own.

Before you jump right in, do you know what exactly a motorized microscope does when compared to a regular microscope? DIY_maxwell explained that, at least for him, it needed to be able to tilt in order to take photos, from an angle, of “highly reflective surfaces (semiconductor chips),” and that it should quickly adjust the focus and magnification, and position of the sample.

“The microscope has a simple operation principle based on changing the magnification and the focus by adjusting the relative distances between a camera, a single objective lens and a sample. Briefly, two linear stages with stepper motors are used to adjust these distances for a continuous and wide magnification range,” the GitHub instructions state. “Four additional stepper motors tilt the camera module and change the X-Y position and rotation of the sample. A uniform light source illuminates the sample either from an angle (reflected light) or from the bottom of the sample (transmitted light).”

The main components of this modular, motorized microscope include a Raspberry Pi system, an 8 MegaPixel camera, six stepper motors, a keyboard or joystick for variable speed control, uniform illumination, and obviously plenty of Lego bricks. Depending on the specific features and electronics vendors used, the whole thing costs between $200-$400, and once you have all the parts in front of you, should only take a couple of hours to assemble.

The main body was built with individually-purchased Lego bricks, and DIY_maxwell designed custom actuators and 3D printed them, rather than using available motors and gears from LEGO Technic.

“This approach not only lowered the cost of the microscope but also gave me some flexibility in the design and implementation of precise linear and rotary actuators. In principle, the whole structure could be 3D-printed without using any LEGO parts but that would be less modular and more time consuming,” he writes in GitHub.

In addition, 3D printing offers you the flexibility of quickly changing the design for maximum optimization if and when it’s needed.

“If the parts do not match well, some minor modification in the original design file (e.g. enlarging the holes matching to LEGO studs) or polishing/drilling may be required,” he explained.

The contents of the motorized microscope are as follows:

Linear Actuators
Camera Module
Rotary Stage
Illumination
Tilt Mechanism
Electronics
Final Assembly
Software

You can find detailed instructions, images, slicer settings, tips, and more on GitHub, and a longer version of the assembly video can be viewed here.

Several other Reddit users who routinely use microscopes related how impressed they were about the project; a geologist mentioned that “starting price can be anywhere between $500 to $1000 for something with that kind of quality” when DIY_maxwell said that his microscope could “easily resolve 10um features.” A pathologist expressed excitement about “a modular system to motorize common non motorized microscopes (Leica, Olympus, etc.).” While the compliment was appreciated by the maker, it was noted that “this microscope is not meant to replace a lab microscope used for medical assessment. No dark-field, no fluorescence, no aperture control, it suffers from chromatic aberration and other optical effects at high magnification, etc.”

“I hope this prototype persuades other DIY-enthusiasts to develop new designs of microscopes.”

If you’re interested in using 3D printing to make your own microscope, you can check out all of the relevant information on GitHub to build this one, or check out the OpenFlexture Microscope project on Wikifactory. This was created as “part of the Waterscope initiative, which by allowing for fast and affordable on-site bacterial testing of the water quality in developing regions of the world, is helping to cope with the diseases caused by bad quality water drinking.”

OpenFlexure Microscope

The OpenFlexure can be built in the classroom and used as an education tool for both students and teachers. Because the 3D printed microscope stage uses plastic flexures, the motion is free from friction and vibration, and the four-bar linkages in the stage can be 3D printed in a single job with no support material.

You can find other open source 3D printable microscopes on Thingiverse as well; happy making!

Discuss this and other 3D printing topics at 3DPrintBoard.com or share your thoughts below.

The post Build Your Own 3D Printed Open Source Motorized Microscope appeared first on 3DPrint.com | The Voice of 3D Printing / Additive Manufacturing.

One of the most exciting developments in 3D printing is non-planar 3D printing for FDM. Fused Deposition Modeling (FFF, Material Extrusion) is the most popular, affordable and widespread 3D printing technology. FDM can print many different materials and has a large number of possible applications. There are some limits to FDM however. Z-axis strength is not optimal and the esthetics of parts are not really great. Regular FDM printers print using a cartesian system that moves upward layer by layer. This works well enough if you consider a printer a box that makes things. But, what if you wanted to make things that were more suited to the real world? Parts such as braces, bioprints, orthotics, insoles, helmets and the like all have to fit humans and humans are rather curvy with many organic round parts. Organic designs generally are a challenge to printers as is reducing stepped surfaces and increasing in layer and intralayer adhesion. What if we could make stronger FDM parts that simultaneously looked better? Non-planar FDM may just do all of that for us. Work on slicing nonplanar surfaces for FDM and testing parts is very promising already.

An Airfoil made by Daniel Ahrens and Co. shows us some of the benefits of non-planar 3D printing.

Additional work on non-planar 3D printing shows us that it may be useful for transparent displays and optics, can be done using existing robot arms, and thanks to Grasshopper and a Slic3r plugin there is even software for it. The combination of non-planar printing with microstructures, gradients, multiple materials and lattices could make FDM an even more versatile technology.

Now nonplanar.xyz hopes to make non-planar 3D printing much more widespread. The company was started by Gabriel Boutin who worked on the Kupol helmet we’ve written about before. Getting your current FDM printer to print non-planar is actually quite complex as you can see from this awesome video below. It also illustrates the results one can get.

At nonplanar.xyz they want to sell us the elongated nozzles we would need, teach us how to go non-planar and give us sample G-Code to get us started. I’m incredibly excited about non-planar FDM and hope that the firm spreads non-planar far and wide. You can buy a nozzle starting from $8.49. An introductory course into path design and path programming is $30. You can also buy Gcode for $10 or $2. The Gcode doesn’t really seem like an amazing deal to me but the course and nozzles seem like a steal given what non-planar can do to expand your 3D printing arsenal.

We asked Boutin why he and the Kupol team got into non-planar printing. He responded that:

“I have been looking for the magic bullet among all the additive manufacturing technologies for the last few years. Like most of us, I was captivated by the brand new and expensive machines. They are capable of amazing results but are they value creation tools?Being part of the NFL helmet challenge to create the most protective helmet ever created, I have screened all the possibilities for manufacturing unique lattices I have created for Kupol Inc.”

nonplanar.xyz’s kit on an Ender 3

It took him a while to get the hang of it.

“I have always disregarded FDM, thinking it was not a real manufacturing process. I was completely wrong. The solution was to push the boundaries of FDM to use its full potential, meaning non–planar paths. It was a scary thing at first because I did not have any knowledge of programming. Nevertheless, I have investigated Rhino Grasshopper to see if a guy like me could succeed in printing a non–planar shape. And I just did it.”

Also, the way that Gabriel looks at non-planar is squarely from the view of a designer:

“Non–planar printing is in fact a workflow that you design or adaptt to the product you want to create. There will never be a single solution for everything because it requires intent. If you want to create an insole for example, you need to define what you want the product to look like and how to achieve this. Once you have invested time into your ”design”, you can use it to print similar shapes and therefore you open the door to custom products at scale.”

I love that he sees it as a workflow and indeed looking at it in this manner would make it seem as an option and “path” to certain products. I feel that this is a far more realistic and healthier approach than to look at everything as a “technology” to replace all others. I was very surprised that Gabriel opted for a low cost 3D printer to introduce the technology with.

I have selected the Ender3 for a simple reason, it was dirt cheap and easy to modify. There are other DIY printers on the market that could be very good choices too. I expect nonplanar.xyz to offer compatible nozzles for those other choices in the very near future.

It is now time to leave the surface!

You can order nozzles now and sign up for the tutorial at their site.

The post Start Non-Planar 3D Printing Today on your Ender 3 with nonplanar.xyz appeared first on 3DPrint.com | The Voice of 3D Printing / Additive Manufacturing.