The reactor is attached to an old heart rate monitor strap and it's powered by a 3 volt battery pack that just slips in my jeans pocket. It's light weight and is comfortable to wear for several hours at a time. In the photos below you can see how bright it is- it easily shines through my t-shirt under normal office lighting conditions and is very bright at night.
Follow along and see how it's made.....
Update: see page six for the new style reactor!
Another update! Many people have asked for a kit and a fellow RPF board member has produced a fantastic kit and said I could post a link. This is a very nice kit for anyone wanting to build a wearable arc reactor-
Step 1: Tools and materials
jeweler's saw (or some kind of saw to cut metal and plastic)
needle nose pliers
And for materials:
thin brass sheet
plastic sheet ( I used Delrin- you can buy Delrin and acrylic sheet from Colorado Plastics)
clear acrylic sheet
copper wire- 22ga and 24ga thickness solid wire
sheet metal- 22ga thickness (.025in or about .5mm thickness)
PCB (printed circuit board)- at least 4" square (Radio Shack sells some that measures around 4.5" x 6")
several small bolts - I used 10ea 2.5mm bolts and 3ea 3mm bolts w/nuts
3 volt battery
11 ea NTE30027 surface mount LED's - I bought them from a local supplier but you can order them here: http://www.cablesandconnectors.com/30000-30.HTM
battery hook up wire
As an option for LEDs and making a circuit board you could use these instead-
I'll make specific notes about the materials used and possible substitutes/workarounds on the specific construction pages.
Please note: be careful cutting sheet metal as the edges can be very sharp and it's pretty easy to cut yourself.
Step 2: Start with the backplate
The easiest way I found to cut out all the parts is to draw the patterns on paper and then glue the patterns to my sheet plastic or sheet metal using rubber cement and cut the patterns out with a jeweler's saw. Then file all the edges and smooth them with sandpaper.
So let's start by making the outer ring/backplate assembly. Begin by cutting a 4" diameter disc from PCB material. There are two copper traces cut (or etched) into this as well as a couple of solder pads on the center so you can solder down the LED's. There are 11 LED's- 10 for the clear ring and one for the center lens. The LED's I used are a surface mount type part# NTE 30027. Even though they are a surface mount component they are pretty easy to solder to the copper traces.The LED's sit directly under a clear acrylic ring and they are spaced 36 degrees apart- just make sure they are all facing the same direction! I simply connected the LED copper traces to the center solder pads and then drilled two small holes and soldered some wires from the back of the board to go to my 3v battery.
Instead of having to make a circuit board and solder all the tiny LEDs you can just get some of these little guys and wire them in parallel-
Just glue them down to a back plate and you're good to go!
The outer ring was cut from some thick plastic sheet- I used Delrin because it cuts well and is pretty durable. A good substitute would be 1/2" MDF sheet. I should have painted the ring silver but I ran out of time......maybe I'll make a machined aluminum ring in the future. There are 10 2.5mm allen head bolts evenly spaced at 36 degree intervals around the ring. I just drilled a pilot hole, then drilled a countersink for the bolt head so it would sit just below the surface of the ring. I actually threaded the holes for the bolts but you could probably just shove them in there with a bit of glue.
The outer ring is glued to the PCB backplate with a hot glue gun. Then run a bead of hot glue over the LED's and the copper traces. This will protect the LED's, help diffuse the light and keep the circuit from being shorted out when the remaining parts are installed.
Now you need a lens for the center. I made mine from acrylic sheet, but you could use just about any kind of lens or clear plastic part that would fit. The thing to remember is that if it is too tall then it will come into contact with other parts later on so watch the height. I used a scotchbrite pad on the lens to help diffuse the LED light.
Next an old heart rate monitor strap was glued and screwed to the backside of the backplate. The two screws went through the PCB and into the outer ring, helping to hold everything together.
Step 3: Make the inner ring assembly
First cut the inner ring from clear acrylic sheet and rub it with a scotchbrite pad (steel wool would also work.)
Now comes the tedious part- there are 20 arms that need to be cut out, bent and then placed around a central ring to form the lower spider frame. The dimensions on this are not critical, but you have to constantly check the fit so that it will fit into your previously constructed backplate assembly. You also have to make sure that the clear ring will fit into the slots cut into the spider arms.
The distance from the outer edge to the opening of where the large notch is approximately .08 inches. The trick is that you will have to adjust the fit of this to your acrylic ring as well as the outer ring. You want the spider to essentially press fit snug into the outer ring. Then fit the acrylic ring to the spider. I can guarantee that you will probably have to do some trimming because the spider is so difficult/frustrating to make so that everything is aligned properly. I had to trim probably every opening to get everything to fit properly.
The easiest way to trim the opening in the spider is to use a small sanding disk with a Dremel tool to carefully trim the opening to fit the acrylic ring. The acrylic ring doesn't have to be a perfect fit as it's held in place by the copper wire wrapped around it.
I cut both the central ring and spider arms from 22 ga sheet steel using sheet metal shears and a jeweler's saw. A dremel tool would also work and will come in handy cleaning up all the rough edges. The finished arms were then welded to the central ring. Then the center bottom ring was cut from steel sheet and welded to the spider frame assembly- note how it is positioned. I was short on time so I left out the additional slots. The bolt holes were threaded for 3mm bolts.
As a substitute for sheet steel you could make the parts from brass or copper sheet and then solder the arms to the central ring and then solder the central bottom ring to the spider frame assembly.The parts could also be made from thin plastic sheet as well and just glued together, but they wouldn't be as durable.
Now you have to make 10 little brass tab thingies. These sit on top of the clear ring after it has been placed into the spider frame assembly and then they are then wrapped with 22ga copper wire. Make sure when you wrap the wire it doesn't stick out too far outside the spider frame arms- make sure to check the fit with the backplate assembly- mine is just a light friction fit. The brass tab thingies should be about the same width as your clear ring and the four little tabs should just stick out over the edges of the spider arms. The last bit is to solder some short 24ga copper wires to the tabs.
Step 4: Make the top ring assembly
There is a central ring that is made from aluminum but it could also be made from plastic and painted silver. It's held on with some thin copper wire and a few dabs of glue from a glue gun.
The last bit is a coil of coper wire that has been formed into a ring. I used wire that was coated red- you could use a marker to color the wire. The wire was wound around a drill bit, formed into a circle and then glued together with a glue gun. The coil ring is then placed around the bolts.
Step 5: Testing and final assembly
Now press the entire assembly into the backplate assembly- note the orientation, making sure everything is aligned correctly. If the fit is really loose, you can put a couple dabs of glue between the wrapped copper wire sections and the backplate to hold everything together.
That's it! Now go finish your Iron Man armor suit...... :)
Step 6: New style reactor
The first thing I did was make a simple model in Sketchup to get an idea what the finished reactor would look like. Note that there are slight changes from the Sketchup model and the finished reactors.
The first thing I made were separate circuit boards for the LEDs. These are different from my original reactor in that they have 100 Ohm resistors connected to one side of the LED to protect the LED from burning out. The circuit boards get wires soldered to them and are then bolted to the stainless back plate with small hex head brass screws.
The spider is made from stainless steel that is welded together. There are four small brass hex head bolts that are threaded into each section of the spider and then they are soldered together to keep them from coming loose. The lenses were turned from clear acrylic and them the outer lens was inserted into the spider and the wire wrapping began. The wire wrapping takes forever since it's pretty hard to keep it straight. There's about 50 feet of wire in each reactor.
The outer ring is turned from thick wall aluminum tubing using a lathe and there are four holes drilled and threaded into the back side so it can be mounted to the stainless steel back plate. There is also a thin lip machined into the front of the ring- this will hold a clear protective lens on the finished piece.
The center piece is also turned from aluminum. There is a lip machined into the back side to fit the small brass screen. The back side is also drilled and threaded for two allen head screws so it can be bolted to the stainless back plate- the screws go through the center lens to hold it in place and the center aluminum piece fits into the stainless spider. There are also several small bras hex head screws that hold the stainless spider to the back plate.
Next the outer ring and clear lens are bolted in place. The clear lens slides into the outer ring from the back and gets a bead of clear silicone to seal it to the outer ring. This assembly is then fitted to the back plate.
Since these reactors were built for a motorcycle they needed to be able to take 12v input power and output no more than 4v. To accomplish this I used a power supply circuit from Adafruit www.adafruit.com/index.php. The power supply is adjustable and can accept up to 20v input- it's a really easy to build kit that works great.
These reactors were a lot more work to make than my original reactors but I think they really came out nice. All in all there's 26 stainless steel parts, 32 laser welded joints, 40 soldered joints, 3 acrylic lenses, 2 machined aluminum parts, 50 micro sized brass hex head bolts, 6 allen head bolts, 50ft. of copper wire, 9 surface mount LEDs, 9 surface mount resistors, 2 circuit boards and 1 brass mesh piece in each reactor- whew!