For the past year, [Adam] has been working full-time on developing a low-cost x-ray system for developing nations. He has more than 3,500 hours into the project. A few months ago, we announced the 2015 Hackaday Prize, with a theme of, ‘build something that matters.’ A low-cost x-ray would certainly matter to the two-thirds of the world’s population that does not have access to medical radiography, making this project a great entry for The Hackaday Prize.
[Adam]’s portable x-ray system consists of an x-ray tube encased in an epoxied, 3D printed enclosure filled with dialectric oil. This tube is tucked away inside a beautiful case with just a single 12VDC input and an easy to understand user manual. This is just very high voltages and x-rays, nothing [Adam] hasn’t handled (safely) before. The real trick is in the imaging, and for this, [Adam] is using a phosphor screen to turn that x-ray exposure into something visible, an off the shelf x-ray sensor, and a prism to adapt the sensor to the phosphor screen.
The results are incredible. After taking a few pictures of what he had on hand, [Adam] can see the bond wires inside the microprocessor of a calculator. That’s more than sufficient for medical imaging – the goal of the project – and cheap enough to send it to the far-flung reaches of the planet.
Continue reading “Hackaday Prize Semifinalist: Low Cost Radiography”
Last January, [DrYerzina]’s sister couldn’t find her cat. The family searched the neighborhood for two hours until the cat came out from underneath a bed, proving once again cats own humans, not the other way around. A solution to this problem would come in the form of technology, specifically as [DrYerzinia]’s entry for the Hackaday Prize, a solar-powered Bluetooth tracking device. Yes, you can go on Amazon or eBay and buy a BLE tracker, but this version comes in a handy package: it’s built of a flexible circuit board to fit just about everywhere, including on the collar of a cat.
[DrYerzina]’s Bluetooth tracker is built around an Bluetooth LE module, with a few added passives, LEDs, and other parts glued and soldered onto a double sided, flexible PCB. To this, he’s added a flexible solar cell and a flexible LiPo battery. All of this is stuffed inside an enclosure 3D printed in flexible filament.
While the Hackaday Prize is filled with wearables, [DrYerzina]’s project is at the forefront of hombrew wearable technology. Nowhere else in the prize have we seen a dedication to making a device that bends. The best part is, he’s actually building a useful device; with just 15 minutes of sunlight a day (a condition very likely for a sleeping cat), this Bluetooth tag can work for weeks.
There are 3.6 Million deafblind people in the world, and by far their greatest problem is one of communication. For his entry for the Hackaday Prize, our own miracle worker on hackaday.io is creating a system that enables haptic communication for a variety of devices. It’s called Tact-Tiles, and instead of creating a single device, [Anderson] is building an entire system that enables a multitude of communication devices for deafblind people.
The basic unit of the Tact Tile system is a small, touch sensitive vibrating pad. These tiny PCBs can be fitted to just about anything, including a wired glove, or whatever haptic interface anyone can dream up. The core of the device is a small PCB that can control 32 of these vibrating pads, and communicates with a smartphone or computer over a Bluetooth connection.
With a little bit of software, the Tact Tiles can be configured an any way imaginable, with mapping individual tiles to letters of the alphabet, mapping gestures to letters, or any combination in between. [Anderson] has a great video demoing the possibility of his device, you can check that out below.
Continue reading “Hackaday Prize Semifinalist: Tact Tiles”
[K.C. Lee]’s entry for the Hackaday Prize won’t cure cancer, wipe a disease from the planet, stop an alien invasion, or save the world. His battery charger and analyzer is, however, a useful little device for determining the charge and discharge characteristics of batteries, and can also be used as dual channel electronic load, current source, or power supply.
Inside [K.C.]’s device are all the tools required for charging and discharging lithium-ion, lead acid, and NiMH batteries. He’s doing this with a few slightly unusual circuits, including a SEPIC DC to DC converter, and an ‘analog’ PWM controller. these two techniques together mean [K.C.] can get away with smaller caps and inductors in his design, which also means less ripple on the output. As far as battery chargers and dischargers go, this one is very well designed.
Control of battery discharging and charging happens through a SILabs 8051-based microcontroller with USB. The UI is a simple Nokia LCD and an app running in Windows. If you want to save the world, this isn’t the project for you. If you need to test a few rechargeable batteries, this is a great device to have on the workbench.
Walk into any home improvement store, and you’ll find dozens of smart accessories, home automation equipment, and WiFi-connected ephemera. The Belkin WeMo Insight is one of these devices, giving anyone with $60 and a WiFi network the ability to switch lights and appliances on and off over a network. [John] picked up one of these WiFi plugs, but it didn’t work exactly as he would like. Instead of building a smart plug from scratch, [John] replaced the controller board for a WeMo Insight for his Hackaday Prize entry, making it far more useful and a replacement for devices like the Kill-a-Watt.
In its stock form, the WeMo can only be used though the smartphone app provided by Belkin or through a few third-party services like IFFT. All of these solutions have a limited API, and don’t provide advanced power metrics. To solve this problem, [John] replaced the smart controller board inside the Belkin WeMo with one of their own design.
By volume, most of the electronics inside the WeMo are a transformer, caps, and a relay; the smarts of this smart plug are just a daughterboard. By re-engineering this daughterboard with a new microcontroller, an ESP8266, and a microSD card connector, [John] can replicate the functionality of the WeMo while adding some new features. SD card datalogging for up to four years is now possible, a RTC now provides precise time stamps on all data collected, and a few simple calculations on the microcontroller enable power factor, line frequency, and total energy metering. With the ESP, all this data can be sent up to the cloud with a vastly improved API.
It’s a great project, and something that Belkin should seriously consider for their next revision of the WeMo. For anyone stuck with a stock WeMo, [John] has made all his design files and code available, allowing anyone to replicate this build
You can check out [John]’s Hackaday Prize entry video below.
Continue reading “Hackaday Prize Semifinalist: A Better Smart Plug”
Many people with Multiple Sclerosis have sensitivity to heat. When the core body temperature of an MS sufferer rises, symptoms get worse, leading to fatigue, weakness, pain, and numbness. For his entry to the Hackaday Prize, [extremerockets] is finding a solution. He’s developing a wearable, personal cooling device that keeps the wearer at a comfortable temperature.
The device is based on a wearable shirt outfitted with small tubes filled with a cooling gel. This setup is extremely similar to the inner garments worn by astronauts on spacewalks, and is the smallest and most efficient way to keep a person’s core body temperature down.
Unlike a lot of projects dealing with heating and cooling, [extremerockets] isn’t working with Peltiers or thermoelectric modules; they’re terribly inefficient and not the right engineering choice for something that’s going to be battery-powered. Instead, [extremerockets] is building a miniature refrigeration unit, complete with a real refrigeration cycle. There are compressors, valves, and heat exchanges in this build, demonstrating that [extremerockets] has at least some idea what he’s doing. It’s a great project, and one we can’t wait to see a working prototype of.
The theme of this year’s Hackaday Prize is to build something that matters, and there is nothing more important than water quality and pollution. Everything we eat and drink is influenced by the water quality in rivers and reservoirs. C4Derpillar, a semifinalist for the Hackaday Prize, is solving the problems of water-related health issues with innovative sensors for under $500 USD per unit.
The C4Derpiller is using capillary electrophoresis (CE) to detect anions and cations in waterways. CE pulls a water sample through a very thin tube with an electric current. As water is moving through this capillary, a sensor is able to detect heavy metals, pesticides, and other pollutants in a water supply. The team behind C4Derpiller has written a few posts about the separation chemistry of their device
Commercial CE equipment costs tens of thousands of dollars. The team behind the C4Derpillar are hoping to develop their pollution monitoring device and make it available for about $500 USD. That’s cheap enough for multiple pollution monitoring stations in the third world, and by pushing the results to the cloud, the C4Derpillar will be able to monitor pollution in real time.
You can check out C4Derpillar’s Hackaday Prize video below.
Continue reading “Hackaday Prize Semifinalist: Water Quality Monitoring”