This project is inspired by a previous instructable from Hellboy and his Lantern Clock. In the meanwhile he came out with the Cyclops which has a kind of similar concept as mine, but God see my heart, I just took the Lantern clock as my starting point. Anyway I would like to thank him for that inspiration.
When I first saw Hellboy's clock, I said I want something like that. So I sat to my desk switched on my computer and started to design. After a while I came up with the final plan.
The rendered 3d image looked quite OK for me.
For the wooden parts I wanted to use wenge wood but I could not get wenge in that size for a reasonable price. So I decided to use the old proven walnut and maple combination.
I realized soon enough that finding a similar brass disks and gears what matching my design is quite impossible so I decided to make them, but I did not know how yet. The turning would kill my little Unimat machine, which set is meant to make small parts not these big ones, so I just put them on hold for a while until I find a solution and start the rest. And lately, the solution came to me by itself.
List of Materials, tools:
-circular saw, scroll saw
-drill and router machines
-brass rods, pipes
-lots of sandpaper
-nixie clock kit
-12v power adaptor
-safety gloves, eye protection
Step 1: The woodwork
I ordered some 5mm thick walnut sheets and cut all of them by laser to have the accurate curves. The cutting shapes are from the 3d design, just had to convert them to vector format.
That was the first time when I have ever used laser cutter, I can tell it is amazing how much work you can save just to use the laser... Of course I don't have a laser cutter at home, but there is one just 2 minutes away from my house in a public Fablab workshop. For a few Euro you can use it.
For the base I bought walnut and maple timber. After planing I glued the print outs of the base shapes and drilled all the necessary holes. My experience to make the holes first, then cut the shape. Where the bigger holes are close to the edge the drill bit or router bit could break off little chips from the wood if you cut the shape first and that is definitely not a good thing. So after having the holes I cut the ovals with my scroll saw. For the PCB panel I made the opening on all 3 base components.
After assembling all the parts the next step was to sanding all of them with a fine grit paper. I applied some dark stain for the walnut parts, the maple remained natural and sprayed them with a metal lacquer. I found it more hard and resistant than the one for wood.
Step 2: The tanks:
The disks and gears on the tanks are made from walnut and brass. I cut the wooden disks by laser. For the brass I bought 1,6 mm, 3 mm and 5 mm thick sheets. The thinner ones are from ebay, from England. The 5 mm sheet was harder to find (for good price), but finally I had them from Germany. After making the proper drawing for them, I took all the sheets to a local waterjet cutting company.
We had some difficulties to find out how to cut these small part without losing or damaging them.
Two things happened, after the cutting head just finished on one of them, the little parts are popped up and fallen to the deep mud under the machine, so I could say goodbye to them, or the bigger disk slightly moved after cutting head just finished the cutting cycle and the loose disk slipped into the water beam and this made some irreversible damage on them. The solution was to leave a little holder beam/rod on each pieces connect them to the sheet and later I could just break them off, like on the plastic model kits what you can buy anywhere.
As soon I have received the ready disks and gears I had to get into polishing. This is always a nice part, you sand and polish everything for days and days, and everything is just a mess, but at the end you have the shiny discs just waiting to be on the final place.
The acrylic holder rims are made from two parts, one outer disk and one inside disk for the acrylic tube. Between them I placed a bolt to screw in the tank holder threaded rods. These main rods on the bottom are holding the base by attaching them to the clock base, the rods on the top are connected to the arms to hold them tight.
The bottom rims are also keeping the Nixie tubes in place.
The top and bottom rims are connected with a 2 mm brass rod with tightening bolts on the two ends. This is strong enough to secure everything in place.
All the bottom disks/gears have two more bigger openings for the Nixie tube wires.
Step 3: The electronics:
After I have finished the PCB I had to wait a while to see if it’s really working, because the tubes are not soldered to the panel, first need to make the place for them, than connect all the legs by wire. So first thing first...
I extended the nixie legs with some wire to reach the PCB. I used black for the anodes and for all the rest I used white wires. I know I should have used some rainbow coloring, but the wires what I could get in different colors were too hard to bend into that small place what I had between the panel and clock base so I had to use some softer ones. Anyway it was not difficult to work with them. I used 4 colors to mark each wire, by colormarks I, II, III. Than I had 4 x 3 color code =12 + 1 anode, so 13 connection point per Nixie tube.
For the hour/minute/second separator neon lights I used the ones what were come with the electronics package, and I placed the to the front of the clock base, inside two 10 mm outside diameter acrylic tubes.
The power connector fixed to the base sandwich along with operating buttons, what I just bought in the local electronic shop. I made some brass tubes around them to match the design.
From the PCB you can optionally run 6 LEDs to the tubes to give some blue or any other colors of extra light. I used only 3 blue LEDs for the 3 tanks.
For the alarm LED, I found one SMD LED, probably from an old CD writer, in my spare parts box in a very nice matching orange color. I decided to place it inside the acrylic holder rim behind one of those design holes around them.
Step 4: The rest:
The spacers (84 pieces) for the laminas and for the base made from 4 mm brass pipe. I polished those along with the visible screws and bolts.
Remember: To protect your eyes is a MUST!
For the bottom of the clock I chose an ABS plastic plate, laser cut it and engraved informations over the buttons and the power requirements. The little holes under the PCB give some ventilation for the electronics.
Step 5: Assembling:
Than I screwed the 3 tank bases to the base and soldered all the wires to the PCB. I left little extra length of wire to have some space to flip to the side the PCB panel.
After connecting and testing the clock the next step was to place the remaining base parts and the preassembled 'laminas'. The next step was to solder the neon, power and button wires and closed the bottom.
For the legs I was thinking a lot what to use, and finally I have found these brass legs in one of the local hardware shop.
The final step to place the tank tops and the arms and plug the power cable to enjoy the clock.
Step 6: The final clock:
That is a good reward for me.