Lathe Outfitted With Electronic Gearbox

Running a metal lathe is not for the faint of heart. Without proper knowledge and preparation, these machines can quickly cause injury or destroy expensive stock, tools, or parts. The other major problem even for those with knowledge and preparedness is that some of their more niche capabilities, like cutting threads with a lead screw, can be tedious and complicated thanks to the change gear system found on some lathes. While these are useful tools for getting things done, [Not An Engineer] decided that there was a better way and got to work building an electronic gearbox to automate the task of the traditional mechanical change gear setup in this video.

What makes change gears so tricky is that they usually come as a set of many gears of different ratios, forcing the lathe operator to figure out the exact combination of gears needed to couple the spindle of the lathe to the feed screw at the precise ratio needed for cutting a specific thread pattern. It is possible to do this task but can be quite a headache. [Not An Engineer] first turned to an Arduino Nano to receive input from a rotary encoder connected to the shaft of the lathe and then instruct a motor to turn the feed screw at a set ratio.

The first major problem was that the Arduino was not nearly fast enough to catch every signal from the encoder, leading to a considerable amount of drift in the output of the motor. That was solved by upgrading to a Teensy 4.1 with a 600 MHz clock speed. There was still one other major hurdle to cross; the problem of controlling the motor smoothly when an odd ratio is selected. [Not An Engineer] used this algorithm to inspire some code, and with that and some custom hardware to attach everything to the lathe he has a working set of electronic change gears that never need to be changed again. And, if you don’t have a lathe at all but are looking to get started with one, you can always build your own from easily-sourced parts.

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A custom LEGO throne for Dune's Baron Harkonnen.

A Throne For LEGO Baron Harkonnen

If you’re both a LEGO and a Dune fan, unless you’ve been living in a cave on Mars with your eyes shut and fingers in your ears, you’re probably aware that LEGO released a set for the royal Atreides ornithopter. The blades flap and everything. Anyway, it comes with several minifigures, including one that doesn’t quite fit with the others — a full-length Baron Harkonnen.

The inner workings of the Baron throne, showing the Baron affixed to his stepper motor. Given that, [gorkyver] decided to create a throne for the Baron that he could rise from, just like in the movie, while delivering the iconic line. With no reference materials available other than pausing the movie, [gorkyver] created a throne from scratch in BrickLink Studio, which made it easy to generate both a parts list and step-by-step instructions.

At the heart of this build is an Arduino Nano, which takes input from the momentary push button and starts the show. The Baron slowly rises on a rack and spur gear connected to a stepper motor, and a DF Player Mini runs the audio through a 75 mm speaker.

Rather than just buying a big box store display case off of eBay, [gorkyver] recreated the skeleton in Fusion 360 and used a hairdryer to bend a sheet of PET-G around to enclose it. A couple of sweet adhesive graphics later, and it totally looks like a real set on display. Don’t miss the demo/build video after the break.

Did you hear? The European Space Agency printed some bricks out of meteorite dust, and there might be one on display near you.

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Using The Moiré Effect For Unique Clock Face

If you’ve ever seen artifacts on a digital picture of a computer monitor, or noticed an unsettling shifting pattern on a TV displaying someone’s clothes which have stripes, you’ve seen what’s called a Moiré pattern where slight differences in striping of two layers create an emergent pattern. They’re not always minor annoyances though; in fact they can be put to use in all kinds of areas from art to anti-counterfeiting measures. [Moritz] decided to put a few together to build one of the more unique clock displays we’ve seen.

The clock itself is made of four separate Moiré patterns. The first displays the hours with a stretching pattern, the second and third display the minutes with a circular pattern, and the seconds are displayed with a a spiral type. The “hands” for the clock are 3D printed with being driven by separate stepper motors with hall effect sensors for calibration so that the precise orientation of the patterns can be made. A pair of Arduinos control the clock with the high-accuracy DS3231 module keeping track of time, and [Moritz] built a light box to house the electronics and provide diffuse illumination to the display.

Moiré patterns can be used for a number of other interesting use cases we’ve seen throughout the years as well. A while back we saw one that helps ships navigate without active animations or moving parts and on a much smaller scale they can also be used for extremely precise calipers.

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Pi Pico Helps Restring Badminton Rackets

Stringing a badminton racquet is a somewhat complicated job. It needs to be done well if the racquet is to perform well and the player is to succeed. To that end, [kuokuo] built a machine of their own to do that very task. Even better, they’ve made it open source so other hobbyists can benefit from their work.

The build is named PicoBETH, which stands for Pico Badminton Electronic Tension Head. It’s based around the Raspberry Pi Pico, as you might imagine. The Pico is charged with controlling the stringing procedure via a stepper motor and lead screw, while using a load cell to measure string tension during the process. A small two-line character LCD serves as the user interface, along with some buttons, LEDs and a buzzer for feedback. The electronic stringing gear is mounted on to a traditional manual drop-weight stringing machine to execute the process faster and more accurately, at least in theory.

Files are on Github for those that wish to explore the build further. It’s not the first stringing machine we’ve featured here, either! Video after the break.
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Customizable Bird Clock Sings The Hours By

For those looking to build their own clocks, one of the easiest ways to get started is with a pre-built module that uses a simple quartz oscillator and drives a set of hands. This generally doesn’t allow for much design of the clock besides the face, and since [core weaver] was building a clock that plays bird songs, a much more hackable clock driver was needed to interface with the rest of the electronics needed to build this project.

The clock hands for this build are driven by a double stepper motor which controls an hour and minute hand coaxially but independently. Originally an H-bridge circuit was designed for driving each of the hands but they draw so little current in this configuration that they could be driven by the microcontroller directly. A DS3231 clock is used for timekeeping connected to an ATMega128a which controls everything else. At the start of each hour the clock plays a corresponding bird song by communicating with an mp3 module, and a remote control can also be used to play the songs on demand.

Bird clocks are not an uncommon thing to find off the shelf, but this one adds a number of customizations that let it fly above those offerings, including customizing the sounds that play on the hour and adding remote control capabilities, a lithium battery charging circuit, and a number of other creature comforts. If you’re looking for even more unique bird clock designs this binary bird clock might fit the bill.

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A 3D-printed clock that uses flaps for the digits that get rotated.

Non-Split-Flap Clock Does It With Fewer Flaps

As cool as split-flap clocks and displays are, they do have a few disadvantages. The mechanism sticks out on the side, and the whole thing relies on gravity. Some people don’t care for the visual split in the middle of each digit that comes as a result. And their cousins, the Numechron clocks? Those wheels, especially the hours wheel, are really big compared to the size of what they display, so the clock housings are huge by comparison.

[shiura] decided to re-invent the digital display and came up with this extremely cool spinning flap mechanism that uses a lip to flip each flap after it is shown. Thanks to this design, only half the number of flaps are needed. Not only is the face of the clock able to be much larger compared to the overall size of the thing, the whole unit is quite shallow. Plus, [shiura] tilted the display 15° for better visibility.

If you want to build one of these for yourself, [shiura] has all the STLs available and some pretty great instructions. Besides the printed parts, you don’t need much more than the microcontroller of your choice and a stepper motor. Check out the demo/build video after the break, and stick around for the assembly video.

Don’t mind the visual split in the numbers? Check out this split-flap clock that uses a bunch of magnets.

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Designing A Quality Camera Slider Can Be Remarkably Satisfying

Camera sliders are great creative tools, letting you get smooth controlled shots that can class up any production. [Anthony Kouttron] decided to build one for an engineering class, and he ended up mighty satisfied with what he and his team accomplished.

As an engineering class project, this wasn’t a build done on a whim. Instead, [Anthony] and his fellow students spent plenty of time hashing out what they needed this thing to do, and how it should be built. An Arduino was selected as the brains of the operation, as a capable and accessible microcontroller platform. Stepper motors and a toothed belt drive were used to move the slider in a controllable fashion. The slider’s control interface was an HD44780-based character LCD, along with a thumbstick and two pushbuttons. The slider relied on steel tubes for a frame, which was heavy, but cost-effective and easy to fabricate. Much of the parts were salvaged from legendary e-waste bins on the university grounds.

The final product was stout and practical. It may not have been light, but the steel frame and strong stepper motor meant the slider could easily handle even heavy DSLR cameras. That’s something that lighter builds can struggle with.

Ultimately, it was an excellent learning experience for [Anthony] and his team. As a bonus, he got some great timelapses out of it, too. Video after the break.

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