We probably don’t need to tell this to the average Hackaday reader, but we’re living in a largely disposable society. Far too many things are built as cheaply as possible, either because manufacturers know you won’t keep it for long, or because they don’t want you to. Of course, the choice if yours if you wish to you accept this lifestyle or not.
Like many of us, [Erik] does not. When the painted markings on his stove become so worn that he couldn’t see them clearly, he wasn’t about to hop off to the appliance store to buy a new one. He decided to take things into his own hands and fix the poor job the original manufacturers did in the first place. Rather than paint on new markings, he put science to work and electroetched them into the metal.
Whether or not you’ve got a stove that needs some sprucing up, this technique is absolutely something worth adding to your box of tricks. Using the same methods that [Erik] did in his kitchen, you could etch an awesome control panel for your next device.
So how did he do it? Despite the scary multisyllabic name, it’s actually quite easy. Normally the piece to be etched would go into a bath of salt water for this process, but obviously that wasn’t going to work here. So [Erik] clipped the positive clamp of a 12 V battery charger to the stove itself, and in the negative clamp put a piece of gauze soaked in salt water. Touching the gauze to the stove would then eat away the metal at the point of contact. All he needed to complete the project were some stencils he made on a vinyl cutter.
We’ve previously covered using electricity to etch metal in the workshop, as well as the gorgeous results that are possible with acid etched brass. Next time you’re looking to make some permanent marks in a piece of metal, perhaps you should give etching a try.
Kids – they’re such a treasure. One minute you’re having a nice chat, the next minutes they’re testing your knowledge of the natural world with a question like, “Why can we see the Moon during the day?” And before you know it, you’re building a CNC Earth-Moon orbital model.
We’ve got to applaud [sniderj]’s commitment to answering his grandson’s innocent question. What could perhaps have been demonstrated adequately with a couple of balls and a flashlight instead became an intricate tellurion that can be easily driven to show the relative position of the Earth and Moon at any date; kudos for anticipating the inevitable, “Where was the moon when I was born, Grampa?” question. The mechanism is based on the guts of a defunct 3D-printer, with the X-, Y-, and Z-axis steppers now controlling the Earth’s rotation and tilt and the Moon’s orbit respectively, with the former extruder drive controlling the tilt of the Moon’s orbital plane. A complex planetary gear train with herringbone gears, as well as a crossed-shaft helical gear set, were 3D-printed from PLA. The Earth model is a simple globe and the Moon is a ping-pong ball; [sniderj] is thinking about replacing the Moon with a 3D-printed bump-map model, a move which we strongly endorse. The video below shows the tellurion going through a couple of hundred years of the saros at warp speed.
There’s just something about machines that show the music of the spheres, whether they be ancient or more modern. And this one would be a great entry into our 3D-Printed Gears, Pulleys, and Cams contest too.
Continue reading “CNC Tellurion Lets You See the Earth and Moon Dance”
[Maurin Donneaud] has clearly put a lot of work into making a large flexible touch sensitive cloth, providing a clean and intuitive interface, and putting it out there for anyone to integrate into their own project.. This pressure sensing fabric is touted as an electronic musical interface, but if you only think about controlling music, you are limiting yourself. You could teach AI to land a ‘copter more evenly, detect sparring/larping strikes in armor, protect athletes by integrating it into padding, or measure tension points in your golf swing, just to name a few in sixty seconds’ writers brainstorming. This homemade e-textile measures three dimensions, and you can build it yourself with conductive thread, conductive fabric, and piezoresistive fabric. If you were intimidated by the idea before, there is no longer a reason to hold back.
The idea is not new and we have seen some neat iterations but this one conjures ideas a mile (kilometer) a minute. Watching the wireframe interface reminds us of black-hole simulations in space-time, but these ones are much more terrestrial and responding in real-time. Most importantly they show consistent results when stacks of coins are placed across the surface. Like most others out there, this is a sandwich where the slices of bread are ordinary fabric and piezoresistive material and the cold cuts are conductive strips arranged in a grid. [Maurin] designed a custom PCB which makes a handy adapter between a Teensy and houses a resistor network to know which grid line is getting pressed.
If you don’t need flexible touch surfaces, we can help you there too.
Continue reading “You Are Your Own Tactile Feedback”
A bioreactor is a useful thing to have in any biology lab. Fundamentally, it’s a tank in which biological activity can be nurtured and controlled. [The Thought Emporium] needed a visual aid for an upcoming video on bioluminescent bacteria, but figured a single test tube full of the little critters just wasn’t visually striking enough. Thus began the build to turn a kerosene lantern into a full-featured bioreactor.
The ideal bioreactor for the project needed to be visually appealing, biologically safe, and to have the possibility for continuous operation. First, the lantern’s base was sealed with aluminium plate and silicone sealant. The top was then fitted with a plastic plug, which contained passthroughs for air and fluid feeds, UV LEDs for luminescence tests, as well as potential sterilization purposes. Wiring was neatly passed through the arms of the lantern, and an air pump hidden in the top. A battery compartment was also installed so the reactor can be portable, even when fully loaded.
The bioreactor was first filled with highlighter ink, and the UV lights switched on, confirming that the reactor does look the part when filled with glowing fluid. Then, it was flushed with hydrogen peroxide, before being refilled with growth medium and an E. Coli strain which produces a fluorescent red protein. Growth was successful, and there are future plans to use the bioreactor for other projects, too.
It goes without saying that it’s important to take the proper precautions when hacking on biological projects, lest you inadvertently create the zombie virus and take down half the population of the eastern seaboard. Regardless, it’s an impressive build that showcases various techniques for working with biological matter that may not be familiar to the home hacker. If you’re looking for more automation for your home biology hacks, perhaps the OpenLH project may interest you. Video after the break.
[Thanks to Baldpower for the tip!]
Continue reading “This Kerosene Lantern Becomes A Compact Bioreactor”
If you’re cutting metal in the workshop, you’re likely using a table-mounted cutoff saw, or perhaps a bandsaw for finer work. The power hacksaw is an unwieldy contraption that looks and feels very old fashioned in its operation. Despite the drawbacks inherent in the design, [Emiel] decided to build one that operates under drill power, and it came out a treat.
The build uses a basic battery powered drill as its power source. This is connected to a shaft which rotates a linkage not dissimilar to that seen on steam locomotives, but in reverse. The linkage in this case is turning the rotational motion of the drill into linear motion of the hacksaw, which moves along a metal rail, guided by a 3D printed bearing.
With a body of plywood and plastic moving parts, this might not be your tool of choice for high-volume, fast paced work. However, as [Emiel] notes, it’s faster than doing it by hand, and it was a fun build that by and large, used what was already lying around the workshop. It’s not the first time we’ve seen a powered hacksaw use 3D printed parts, either. Video after the break.
Continue reading “This Home Made Power Hacksaw Cuts Quick And Clean”
Word clocks are one of those projects that everyone seems to love. Even if you aren’t into the tech behind how they work, they have a certain appealing aesthetic. Plus you can read the time without worrying about those pesky numbers, to say nothing of those weird little hands that spin around in a circle. This is the 21st century, who has time for that?
Now, thanks to [Gordon Williams], these decidedly modern timepieces just got a lot more accessible. His word clock is not only small enough to fit in the palm of your hand, but it’s the easiest-to-build one we’ve ever seen. If you were ever curious about these gadgets but didn’t want to put in the the time and effort required to build a full scale version, this diminutive take on the idea might be just what Father Time ordered.
The trick is to attach the microcontroller directly to the backside of an 8 x 8 LED matrix. As demonstrated by [Gordon], the Bluetooth-enabled Espruino MDBT42Q fits neatly between the rows of pins, which need only a gentlest of persuasions to get lined up and soldered into place. Since the time can be set remotely over Bluetooth, there’s not even so much as an additional button required. While driving the LEDs directly off of the digital pins of a microcontroller is never recommended, the specifics of this application (only a few of the LEDs on at a time, and not for very long) means he can get away with it.
Of course, that just gets you an array of square LEDs you blink. It wouldn’t be much of a word clock without, you know, words. To that end, [Gordon] has provided an overlay which you can print on a standard inkjet printer. While it’s not a perfect effect as the light still comes through the ink, it works well enough to get the point across. One could even argue that the white letters on the gray background helps with visibility compared to just the letters alone lighting up.
If you’re not in the market for a dollhouse-sized word clock, fear not. We’ve got no shortage of adult sized versions of these popular timepieces for your viewing pleasure.
Continue reading “Is That A Word Clock In Your Pocket?”
There’s a line from the original Star Trek where Khan says, “Improve a mechanical device and you may double productivity, but improve man and you gain a thousandfold.” Joan Horvath and Rich Cameron have the same idea about improving education, particularly autodidacticism or self-learning. They share what they’ve learned about acquiring an intuitive understanding of difficult math at the Hackaday Superconference and you can watch the newly published video below.
The start of this was the pair’s collaboration on a book about 3D printing science projects. Joan has a traditional education from MIT and Rich is a self-taught guy. This gave them a unique perspective from both sides of the street. They started looking at calculus — a subject that scares a lot of people but is really integral (no pun intended) to a lot of serious science and engineering.
You probably know that Newton and Leibniz struck on the fundamentals of calculus about the same time. The original papers, however, were decidedly different. Newton’s approach was more physical and less mathematical. Leibniz used formal logic and algebra. Although both share credit, the Leibniz notation won out and is what we use today.
Continue reading “Understanding Math Rather Than Merely Learning It”