Fusor progress, Antoine Fleitz
Posted: Wed Jul 11, 2018 1:09 am
Hello,
I started building a fusor in fall 2015.
Money being the “nerf de la guerre” (sinews of war), I believe it’s always important to remember that building a fusor isn’t cheap.
In almost three years I’ve spend around 2.000US$ in this endeavour plus 450US$ for port and import taxes.
I’m using US currency here as a common denominator and also to not discourage fellow Canadians with numbers inflated by the painful USD/CAD conversion rates these days.
Speaking of US/CA disparity, note that it’s cheaper to ask for delivery on the other side of the border and go get your package but it comes with having to explain to the customs agents on both sides what you are moving across (did you say nuclear?). Thus the use of this strategy depends as much on your wallet as it depends on your mood.
To date, the most expensive single part I bought has been the 6” spherical vacuum chamber (600US$) with three ports that luckily I found assembled on eBay last year.
Vacuum pumps and gauges were less than 200US$ each.
Aside from eBay, I bought at greater expense some stuff I prefer to have new (viewport and HV feedthrough), from LDS and KJ Lesker.
I started with the vacuum system because I believe it to be the most versatile part of a fusor (in case I changed my mind).
My vacuum setup is based on an used diffusion pump (maybe an Edwards) coming from ORNL (certified free of active radionucleides) backed by an Alcatel 2004A (patriotism obliges) two stages mech pump I had to patch.
The above-mentioned diffusion pump is cooled by a PC water-cooling setup I will have to improve.
Connections are mostly KF25 except on the vacuum chamber (2x2.75CF and 1.33CF) and diffusion pump (ISO-100).
Two valves isolates the pumps. One for rough vacuum and the other for high vacuum.
As there are only three ports on the vacuum chamber, deuterium will be fed via a double sided 2.75CF flange with side holes.
To get an idea of what’s going on inside, I was using an old CVC GTC-036 thermocouple at first but then came upon a nice Pirani gauge and it’s controller. I recently added an ion gauge (W filaments) to that same controller to test more thoroughly the whole assembly performances.
To date, min pressure measured was 5.5E-6 Torr after two hours of pumping. Given more time it could certainly go lower. Leak rate, HV valve closed, was about 3E-3 Torr/min and stable after four pump runs.
The whole thing is held in place by an Ikea kitchen cart. I’m not the first one to use this culinary tool for a high vacuum system since I took the idea from the Applied Science guy on YouTube.
This arrangement being now operational, I’m focusing on the deuterium and electric sides of the project.
Neutrons detection will be the last step but for once it should be cheaper than usual given that bubble detectors are coming from Ontario.
If everything goes according to plan I should be able to fuse some nuclei before the end of 2018.
I started building a fusor in fall 2015.
Money being the “nerf de la guerre” (sinews of war), I believe it’s always important to remember that building a fusor isn’t cheap.
In almost three years I’ve spend around 2.000US$ in this endeavour plus 450US$ for port and import taxes.
I’m using US currency here as a common denominator and also to not discourage fellow Canadians with numbers inflated by the painful USD/CAD conversion rates these days.
Speaking of US/CA disparity, note that it’s cheaper to ask for delivery on the other side of the border and go get your package but it comes with having to explain to the customs agents on both sides what you are moving across (did you say nuclear?). Thus the use of this strategy depends as much on your wallet as it depends on your mood.
To date, the most expensive single part I bought has been the 6” spherical vacuum chamber (600US$) with three ports that luckily I found assembled on eBay last year.
Vacuum pumps and gauges were less than 200US$ each.
Aside from eBay, I bought at greater expense some stuff I prefer to have new (viewport and HV feedthrough), from LDS and KJ Lesker.
I started with the vacuum system because I believe it to be the most versatile part of a fusor (in case I changed my mind).
My vacuum setup is based on an used diffusion pump (maybe an Edwards) coming from ORNL (certified free of active radionucleides) backed by an Alcatel 2004A (patriotism obliges) two stages mech pump I had to patch.
The above-mentioned diffusion pump is cooled by a PC water-cooling setup I will have to improve.
Connections are mostly KF25 except on the vacuum chamber (2x2.75CF and 1.33CF) and diffusion pump (ISO-100).
Two valves isolates the pumps. One for rough vacuum and the other for high vacuum.
As there are only three ports on the vacuum chamber, deuterium will be fed via a double sided 2.75CF flange with side holes.
To get an idea of what’s going on inside, I was using an old CVC GTC-036 thermocouple at first but then came upon a nice Pirani gauge and it’s controller. I recently added an ion gauge (W filaments) to that same controller to test more thoroughly the whole assembly performances.
To date, min pressure measured was 5.5E-6 Torr after two hours of pumping. Given more time it could certainly go lower. Leak rate, HV valve closed, was about 3E-3 Torr/min and stable after four pump runs.
The whole thing is held in place by an Ikea kitchen cart. I’m not the first one to use this culinary tool for a high vacuum system since I took the idea from the Applied Science guy on YouTube.
This arrangement being now operational, I’m focusing on the deuterium and electric sides of the project.
Neutrons detection will be the last step but for once it should be cheaper than usual given that bubble detectors are coming from Ontario.
If everything goes according to plan I should be able to fuse some nuclei before the end of 2018.