Wednesday, December 30, 2015

Portable DIY X-Ray Source & Radiography

Intro.
X-rays, "rays of the unknown" as they were first called, marveled all they encountered since their discovery in 1895 by Wilhelm Roentgen. Given my background and familiarity with radiation, physics, and electronics, making an X-ray unit was only a matter of time. Even though many have done this before me, and if boiled down to its essence it is nothing more than applying the correct power to the correct vacuum tube, it is still quite an accomplishment. Much of the wonders of the world lose their appeal when distilled too far, after all, so let's not get too complacent and forget how great it is what we are achieving here.

SAFETY.
Before I go any further, I want to explicitly point out that I possess and employ the use of adequate safety procedures and equipment during all activities related to the construction, operation, and use of this device. Everything from radiation detection equipment to radiation shielding, to electrical and fire safety equipment is employed to ensure a safe adventure in radiography. If you do not *intimately* understand the hazards and means of minimizing said hazards involved in such a device, please never, ever attempt this. You can seriously injure yourself or any bystanders, even ones outside of the immediate operation area. Potentially, you could even kill yourself. THIS IS DANGEROUS.


The Nitty Gritty Basics.
So, how about a paragraph on the internal process of generating X-rays? Simply put we're accelerating Electrons and then smashing them at a very dense metal target. The electric field of the nucleus of the high density target atom slows down and scatters the incident fast electrons. During the braking effect, the electrons emit a continuum spectrum of x-ray photons as a means of releasing energy. This is Bremsstrahlung Radiation, or "braking x-rays". The maximum energy of the emitted photons is the maximum speed of the incident electrons; a 70kV accelerated electron can emit a 70keV photon. Secondly, the electrons bound to the high density target atom can get knocked out of place. When this happens the electrons in the upper levels of that excited atom fall down to fill the void of the ejected electron. The electron that falls to fill the void emits a x-ray photon as a means of releasing excess energy. This is akin to fluorescence, and is indeed referred to as XRF - X-ray fluorescence. The energy of the emitted photon is a characteristic of the atom that released it. Target atoms typically have a few discrete energies emitted by characteristic XRF.

Operational Mode of my Tube.
So, in our Coolidge tube as invented by William Coolidge in 1913, we apply a high positive voltage to the Anode (which is constructed of a high density metal, tungsten in my tube, and surrounded by copper as a heatsink) in respect to the Cathode. The cathode here is actually a filament made of tungsten which we pass a high current at low voltage through, like a light bulb. When the tungsten reaches about 2000C it emits copious amounts of electrons all around it in a cloud. This is often referred to as "boiling off electrons". These electrons are accelerated towards the high voltage anode via electrostatic attraction. As my tube is a modern coolidge tube designed for dental radiography it has a third electrode inside; the Wehnelt Cylinder Electrode. This was invented by Arthur Wehnelt in 1903, and is essentially an electrostatic lens. Its function is similar to that of a screen grid in a standard thermionic valve vacuum tube; to repel or attract electrons from the cathode. Unlike in a standard valve tube, where the grid is between the cathode and the anode, in our x-ray tube it is behind the cathode. Here it acts as an electrostatic reflector and focuser to shape the cloud and resultant beam of electrons. It would also accelerate the electrons towards the anode, but by a negligible amount compared to the effect of the anode's high positive voltage. Since our grid is behind the cathode, it doesn't use a positive voltage in respect to cathode to allow/enhance flow of electrons to the anode, it needs a negative voltage! Think of it this way, instead of pulling electrons closer to the anode, it is pushing them away from it self, towards the anode. I do not currently have a bias supply set up for the Wehnelt electrode in my tube, which would use between -100V and -500V. Fortunately, most dental tubes operate just fine with the Wehnelt electrode held at Cathode potential, the result of course being far simpler implementation of the tube at a reduced clarity in the resultant radiograph. I may add this supply in later, as I already have an idea on how to achieve this inexpensively and easily. It would of course require I modify the existing setup, and if you've seen the photos of my build, you'll know that means messing with a bunch of messy mineral oil.

Datasheet? I don't need no stinkin' datasheet! ...Oh wait, I wish I had one...
Since the datasheet for my tube was unavailable, and it is no longer in production, I had to determine filamentary specifications empirically. Thankfully I had some guidance from the helpful folks at 4HV.org. Among all the challenges involved in making your own x-ray machine, not having the specifications of your x-ray emission device is no small hill amongst the mountains! Not wishing to vaporize or sever my filament, I couldn't just use figured supplied with modern incarnations of my tube and hope for the best. I had to start conservatively and ease the cathode into operation, despite the risks of shortened cathode life that a normal filament cathode endures if run at too low of a voltage. Fortunately, in x-ray heads the amount of X-rays produced, or x-ray flux is controlled via the filament voltage. Emitting more electrons means more electrons strike the anode, which results into more x-rays emitted.

Initial Testing.
I first connected my coolidge tube to a small low power pulsed HVDC supply in the form of a VCO controlled modern Flyback transformer. Here the currents available are quite small, and the voltage sags greatly under load. Output is between 15kV and 55kV at several mA to a few hundred uA (respectively); sufficient to cause bremsstrahlung x-ray flux levels needed to do initial emission present/not-present testing but no where near enough to do radiography. With this crude setup I was able to determine that 1.95V is the minimum filament emission voltage. Below this point, while the filament is glowing quite bright, no x-rays are produced. It should be noted that because of the pulsed nature of the DC supply and very low levels of x-ray flux produced I was able to use a standard SBM-20 Geiger Muller tube detector. The detector was faraday shielded with 1mm aluminium to rule out false positives from electromagnetic noise, and to reduce the response to very soft x-rays. Now I knew the absolute minimal filament voltage, and it isn't something absurdly low (like under 1.5V would be).

Planning and Sourcing Parts.
Initial planning was done several years ago when I first decided that I would have a responsible use for a radiography setup. I would either find a suitable x-ray transformer and rectify and filter the output, or I would generate suitable HVDC via a common HVAC transformer such as an AC flyback or NST and then amplify the output voltage using a Cockroft-Walton Voltage Multiplier. I ended up going with the latter as X-ray transformers are expensive and hard to come by, where as CW Multipliers are inexpensive and easy to make, and while still rare, AC flyback transformers are a lot cheaper and easier to source. So, I knew what parts I needed; a CW multiplier, an HVAC transformer, an x-ray tube, a transformer driver, a variable voltage filament supply, an enclosure suitable for high voltage oil potting, and finally a remote trigger or controller for safety.

The CW multiplier is easily made from parts available on eBay. If you derate the current, voltage, and capacity specifications on chinese eBay parts they tend to perform well. I chose a 66% derating factor. 30kV 100mA diodes and 30kV 3.3nF capacitors. The caps are actually right on spec capacitance wise, which is nice.

A good friend of mine, Fiddy, came to me a few years ago asking about having custom AC flyback transformers made to order by a Chinese manufacturer. He was unsure of specifics of the design and wanted me to consult for him on the order. I obliged, requesting only a transformer from the resultant batch as payment. His transformers are quite excellent, and he still sells them from time to time. If you want one, contact him on 4HV.org or laserpointerforums.com , tell him Sig sent you. Anyway, I used his transformer for a few temporary projects over the years but saved it for use in my eventual x-ray machine build.

The x-ray tube took the most time to actually track down inexpensively. A nice couple was selling off some things their father had after he passed, and decided to list two Toshiba D-138B Coolidge tubes on eBay at less than 25% the normal going rate as they did not know much/any information about them. SCORE!

Container/enclosure is a $1 polyethylene bin from walmart.

The transformer driver I actually picked up from eBay a year or two ago. It's an inexpensive chinese made Royer type parallel-LC oscillator designed for ZVS operation of an air-core coil for induction heating. It works equally well for flyback transformers if you size the primary coil correctly and watch the peak voltages and currents. I could have easily designed and built a better driver, but honestly you can't beat chinese-made eBay prices. My driver would have cost me twice as much in parts alone. This driver uses about 160W and outputs about 150W when connected to Fiddy's transformer, quite good efficiency. The peak voltage across the LC tank is about 30V when supplied with 13.8V input, and circulating current is over 150A. A good engineer knows when to use an off the shelf solution.

For filament supply I am using my variable bench PSU, but I do have a variable dc-dc buck converter on order that will fill this role and allow for truly portable operation.

Lastly, I picked up a very inexpensive radio controlled relay on eBay for use as a remote trigger controller. It allows for latching and non-latching operation and uses a 300MHz radio. It works great, has excellent range, and doesn't suffer any interference from both the EM noise from the HV power supply or the incident stray x-rays. I use it in non-latching mode for maximum safety.

For HV insulation I am using Mineral Oil, which is available over the counter as laxative. Yes, I'm quite sure I got strange looks when I bought eight bottles of laxative. The things I do for science!

Minor parts: I am using nylon strapping to secure and aim the coolidge tube, as it is nonconductive and durable. I'm using nylon 6-32 x 2" standoffs as mounting posts. All screws and nuts are 6-32 UNC, both nylon and steel. Nylon zip ties secure the AC flyback transformer. A folded thin polyethylene bag serves as additional primary-core insulation on the flyback as well.

Build Pictures!







The Build is "Finished".
The build is essentially finished. Note all above photos are from before oil was added. I just have to install the DC-DC buck converter for the filament supply once it comes in and that's a 10min job at most. If I decide to implement Wehnelt bias then I'll have to dig in and sever the junction between it and the cathode, and then add a line from the Wehnelt pin to a new bushing, install a new bushing, and mount the Wehnelt supply. Probably an hour's job of tedious, but not hard work. I have ordered new X-ray intensifier screens though and I will see how the results are with them before I put in the effort, time, and money to add a Wehnelt bias.

After all, you can have the best lighting rig in the world but if your camera is terrible then your pictures will be terrible!

Radiography Awaits!
Well, my cameras are most certainly not terrible. In fact they're quite excellent, however since x-rays are not focusable with glass and are not directly observable with traditional cameras there has to be an intermediary device for converting X-rays into visible wavelengths. Enter the X-ray Intensifier Screen (XIS). (Un)fortunately the XIS I have been saving for nearly a decade is extremely old, from the 1950s or 1960s, and even more unfortunately it is a BLUE EMISSION type phosphor screen. The emission spectra seems to be mostly between 405nm and 450nm, with a peak around 425nm. It is also a "Rapid" screen, meaning it has very large granules of phosphor which will respond faster, resulting in lower exposure times at the cost of image clarity. While this is all well and good for using an actual film with good UV/NUV/Blue sensitivity, it is rather poor for use with a modern digital camera. Even when using my Full Spectrum camera, which can perceive UV through IR, the response will be much lower than if I had a GREEN EMISSION XIS because of the internal Bayer Filter on nearly all digital cameras which has twice as many Green Pixel Sensors than Blue or Red. Still, I'm a competent Photographer, I should be able to work around this, especially since I'm not x-raying living tissue, so dose (exposure time) isn't a concern. I have since ordered some new Green XIS cartridges in both the Fine and Regular speeds, which should greatly enhance results.

My First Radiograph.

Here we see the internals of household mains electrical wall power switch. I hadn't even begun to determine what the right exposure times, anode current/filament voltage/X-ray flux, or positioning setup would be. Here I simply gave things a "best guess" and saw what resulted. Contrast isn't great, there's a ton of noise, the projected image is skewed, etc. As a photographer it makes me cringe, but upon seeing the raw image I was ecstatic! I had achieved a real radiograph. The culmination of years of planning and scrounging parts bore fruit! What was next was a tremendous amount of work...

System Limitations Impose Interesting Operational Paradigms.
I first began by leaving photographic parameters fixed. I needed to work out the radio-electric parameters. According to the basic principles of operation the Anode current is directly proportional to the X-Ray emission flux. Increasing the X-ray flux increases the brightness of the resulting XIS image, increases the contrast of the image (only between full absorb and full transmit regions, not the contrast gradient between different densities), and results in shorter exposure times. Shorter exposure times are one of the holy grails of photography, even more so for radiography.

So, increase the filament voltage; boil more electrons off, increase x-ray output, decrease exposure time. That's all well and good in a professional x-ray unit where the capabilities of the HVDC supply meet or exceed the capabilities of the x-ray tube. Unfortunately, I didn't, and still to an extent don't know the capabilities of the x-ray tube. As such, my power supply cannot supply the full anode current the x-ray tube is capable of drawing. I found this out when during my careful study of and experimentation with the relationship between filament voltage and the resultant radiograph the penetrating ability of the x-rays seemed to diminish above a certain filament voltage. This is clear sign of a "sagging" HV supply. As the current draw increases the CW Multiplier is unable to fully charge its capacitors with the current available from the AC Flyback. The more output current is drawn, the less and less the capacitors are able to charge. The result is the output voltage from the multiplier drops. Less voltage on the Anode means that the resulting Bremsstrahlung x-rays are softer and softer as the peak photon energy drops. This can be useful for imaging low density or very thin subjects, but generally is undesirable as the lower the energy of the x-ray the more easily it is absorbed by living tissue, making the radiation even more dangerous. This is one of those times when you can say your device's bug is a feature, but it's really still just a bug. The only thing that determines if it is a bug or a feature is original intent. Any gamer can tell you that!

Interestingly, while probing the upper end of usable filament voltage / x-ray softness I discovered a hard cutoff effect of the tube. At 3.0V filament the anode current draw is such that either the HV supply completely loads down below minimum B+ rating of the tube, or the x-rays are so soft that they cannot penetrate the envelope with sufficient flux to illuminate the XIS, or the XIS is unable to fluoresce at such a low energy illumination. Since I don't have a means of measuring the anode current or voltage directly I am unable to differentiate between these possible explanations. If I happen upon an analog galvanometer type milliammeter I will investigate further. For now the interest is merely scholarly as I am not going to rework or replace the HV supply, so I will have to live with these characteristics of the device.

This leaves me with a usable filament range of 2-3V, with the apparent "sweet spot" between hardness and flux at about 2.65 Volts DC. X-Ray hardness at this point is sufficient for penetrating thin aluminium quite well, and the flux is at close to 85% of the observed maximum. Below this point I get harder x-rays, but must increase exposure time greatly. Above this point the x-rays get much softer, but the exposure times shorten moderately.


An Important Note about your Anode.
I feel I should take a moment to talk about another important limitation on the operation of x-ray tubes; anode dissipation. The anode has to be a tremendous amount of power flowing through it. More so, it has this power directly striking it. Interesting bit of knowledge; a thin piece of wire can conduct hundreds of watts of power supplying an electrode that is emitting a spark/arc/streamer, but if that same wire were to be the point at which the arc is emitting it will overheat and vaporize or melt very quickly. The thermal effects of ions and electrons are not to be underestimated. The tube's anode can only "sink" so much heat, and that heat needs to wicked away and removed from the system. The heat load also needs to be under a threshold that would cause damage to the target surface. In short pulse exposures the heat deposition rate can actually exceed the speed at which the anode material can move heat away from the target spot, which causes ablation and thermal stress on the anode. Given that my tube doesn't have a biased Wehnelt electrode and the fact that my tube is clearly sagging my power supply there is little threat of exceeding the thermal limitations of my tube's anode. Additionally, I have submerged the entire tube in electrically insulating yet thermally conductive oil, aiding removal of heat. If I add Wehnelt bias I will have to revisit the thermal performance, but I doubt it will be an issue.

Well, without further ado, shall we see some more of my radiographs?

Here from L to R is a Bluetooth Audio Receiver, a wallwart SMPS, a bare double-sided PCB.

Here is a glass vial of sodium metal (Na) chunks in mineral oil next to the SMPS above. The vial is on top of a small bismuth metal (Bi) ingot, and the SMPS is on an empty polyethylene wire spool.

Here we can see the internals of a Mobius ActionCam mini-camcorder.

Here we have a somewhat skewed image (in two axes) of a Kill-a-Watt meter. Despite the very noisy/grainy radiograph you can clearly make out the ribbon cable connecting the two boards and the display driver's ceramic potting compound on the center of the upper board.

Here is the bottom half of my LCR/BJT/FET meter and tester. You can see the 9V battery, several potentiometers, and a microcontroller quite clearly. The blobby bit on the bottom right of the pcb is a ZIF interface slot which has a fair bit of steel in it.

Here is a rather clear image of a radiotelemetry receiver unit. You can clearly see the AAA batteries, their contacts, the main PCB, and the internal wiring. I believe this image to show the maximum clarity achievable with my current XIS. The radio-electrical specifics of this exposure are that of my observed nominal operation point. You can see a good differentiation between the densities of the plastic, metal, battery internals, and pcb components. Any harder x-rays and the case would be totally transparent, any softer and the battery internals would not be visible.

Here you can see a minimally enhanced "raw" image from my setup. In post processing I adjusted the histogram to maximize brightness, contrast, and correct for exposure errors. I intentionally left the channel data close to original so that the XIS color could be observed.  Pictured in the radiograph is a precision 1ohm resistor mounted in an aluminium heatsink, on top of which is an EOL HeNe laser tube. You can clearly see inside the "cathode can" of the tube to see where the bore ends, something I've always wondered about. The spool of solder and zeiss lens wipe are illuminated by reflected blue light emitted from the XIS. I've been using the zeiss wipe as a focusing aide to assist with getting the focal plane where I want it since I'm using manual focus of a very wide aperture telephoto lens.


Looking Forward.
I have some fun times to look forward to with the two new XIS and buck converter coming in the mail in the next few weeks. Once they're all here I can position the x-ray unit, object to be imaged, XIS, and camera freely without being tethered to my workbench. This will not only enhance safety and ease of setup and use, but should result in clearer images as the focal plane of the camera will match the image plane of the XIS. I will be able to try first-surface projection as well as transmission projection (which was used in all of the above images). Eventually I plan to save up for RadMax lead sheeting which I can use to lead line a wooden box enclosure that I plan to build for the unit. This would allow me to be in the same room as the x-ray source. Perhaps I'll keep looking for a proper x-ray transformer and make a pseudo-professional unit out of my spare coolidge tube. After all, this build is more of a prototype than a finished project.

One last thing... a tribute to some great men of times past.
May my Grandmother and Mother never read this. I couldn't help myself. After finishing nearly fifty radiographs and completing all of the operational experimentation I could think to do I had one thing left to do. It was against my better judgement, and in fact I said all along I would never do it. I did carefully assess all the risks involved, and while it was and remains still a seriously stupid irresponsible shit-for-brains thing to do, it wasn't calculated to present a likely chance of injury. You probably already know what I am talking about and what I did. How could I not? Were you in my shoes would you have done differently? As much as I like to justify it to myself by reminding myself that all the greats... Roentgen, Tesla, Crookes, Coolidge, the Curies, and countless more did it too, it is glaringly clear that they did NOT know the risks, and I do/did. Still, time has passed since my... lapse in judgement... and no harm was done. I was lucky. That being said... I am never fucking doing that again. I felt like Louis Slotin the whole fucking time. Talk about instant regret. If you don't know who that is, click the link and learn about a great man who met a tragic end. Note; I placed aluminium plates on the x-ray output to filter out the most dangerous soft bremsstrahlung x-rays, leaving only the hardest rays. I also used full-body shielding of 2mm sheet steel to protect myself. I also cut exposure time to half that of normal. So, I present to you...

"Hand Mit Ringen"
Traditional negative image view:
43,825 Days Ago (120 years and six days) Wilhelm Roentgen took the very first Living Tissue Radiograph. He used his wife's hand, though, a matter which I would never attempt. No, I substituted in my hand instead. Never impose on others what you are unwilling to impose on yourself. No judgement placed on our forefathers and foremothers, for they knew not. You can see Roentgen's radiograph here: The First Radiograph 

By the way, I'm almost certain it was purely psychosomatic but for about an hour after I felt what could only be described as a UV burn on the area. There was no redness, no dryness, no changes at all to see. I've had real UV burns, this was far less verifiable, yet felt similar. The short duration and lack of visible changes leads me to believe it was not after all a soft x-ray burn. Also, more than the area in which I felt the sensation received equal, if not increased exposure. In any case reckless stupidity is out of my system, this was the first and last autoradiograph.

Just a little update: It definitely was psychosomatic. No harm was done (miniscule stochastic effects aside). Also, main beam output seems to be about 100Roentgen/hr (30mR/sec)! This puts my total estimated received dose from the one and only exposure at about 125mR. That's 14 months of background radiation, with most of that being only to my left hand.




13 comments:

  1. Great work. But don't you need to get an approval before making Radio Active components from a Local Governing Body. I remember one guy tried to make a Nuclear Reactor in his Kitchen and tried to get approval from the Governing Body. Next thing, Police stormed his house and arrested him.

    What you have achieved is indeed dangerous. But you are a pro. Thumbsup.

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    1. Hello, and thank you! Yes, building a reactor of any kind, or even possessing quantities of certain isotopes above specific limits is highly illegal. However, concerning x-ray equipment there are only two laws: 1) unlicensed individuals may not use unlicensed equipment on any other person or animal for any purpose. 2) the device must not be used in an unlawful or negligent manner. So, constructing, owning, and using my device is completely legal as long as I follow proper safety guidelines making sure no one is exposed, even accidentally.

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    2. Are you sure about that? I thought that building a fusor was ok.

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    3. Same rules apply to a fusor, or X-ray Fluormeter/Spectrometer, laser, or even a Scanning Electron Microscope; as long as it is not used for illegal purposes, and it is operated in a way that does not damage property or persons it is fine.

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  2. good for you, this is very interesting and inspiring reading

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  3. Averaging a few images will bring out contrast detail by removing some of the noise. Also you can shoot and composite at several energies for a wider dynamic contrast. Add a collimators to reduce scatter. Bias the raw data to zero will help reduce scatter effects also.

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  4. Great information...Your post the very informative i have learned some information about your blog thank you for Sharing the great information.....Digital X ray Machine Price

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  5. is it successful design??can we get dental x-ray by this design??

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  6. Hi Matt, great blog! You can reduce scattering by adding copper or aluminium filter between your source and target. Note that bremsstrahlung and scattered xray is the most unhealthy so consider shielding your manufactured piece with atleast 4mm of lead to reduce it's dose to surroundings. This also helps with image generation, your beam is well collimated and the filtered xray beam forms more clear image.

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  7. This comment has been removed by the author.

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  8. Excellent essay.

    Matt - the phosphor screen... is the light it produced bright enough to be very visible to the naked eye? Or did you have to make very long exposures in order to see it "after the fact" ?

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  9. excelente amigo esta muy interesante he inspiradora

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