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How to Build an X-ray Machine

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Abstract

When you have your X-rays taken at the dentist's or doctor's office, do you ever wonder how the X-ray machine works? Or better yet, how you could make one yourself to use for experiments? This how-to guide provides detailed instructions for high school students and adult do-it-yourself (DIY) enthusiasts to construct and use a homemade X-ray machine safely.

Summary

Areas of Science
Difficulty
 
Time Required
Long (2-4 weeks)
Prerequisites
A basic understanding of radiation and radiation safety is necessary before starting this science project.
Material Availability
Many of the items for this science project, including the x-ray tube, need to be specially ordered. See the Materials & Equipment section for more details.
Cost
Very High (over $150)
Safety
A good understanding of radiation safety, proper radiation shielding materials, and supervision by an adult are required for this science project. The X-ray machine must be operated in a properly shielded place away from passersby. The X-ray machine requires a high voltage power supply; the output from the voltage supply can be deadly if mishandled.
Credits

Matthew Feddersen, 2011 Summer Science Fellow
Sandra Slutz, PhD, Science Buddies
Teisha Rowland, PhD, Science Buddies

Objective

Construct and use a homemade X-ray machine safely.

Introduction

This is a resource for making and using a homemade X-ray machine safely. The homemade X-ray machine can be used to do many relevant experiments, including but not limited to testing how X-rays affect microorganisms, such as yeast, and developing the best X-ray images using film. This resource was made possible by two enthusiastic high school students who developed this homemade X-ray machine to help them not only answer their many scientific questions, but also go on a fun scientific adventure.

A plan for a homemade X-ray machine, an idea about how to increase the localized dose of radiation to cancer cells, and hours of researching, experimenting, and innovating—these were the ingredients for Matthew Feddersen and Blake Marggraff's success at the 2011 Intel International Science and Engineering Fair (ISEF). Together, Matthew and Blake took home the top ISEF prize. As a Science Buddies 2011 Summer Science Fellow Matthew agreed to share his expertise about how to create a homemade X-ray machine.

You can build an X-ray machine at home by carefully following this how-to guide. However X-rays, like other forms of radiation, can be dangerous. To safely build an X-ray machine and experiment with radiation, you must read all parts of this guide as well as an Introduction to Radiation & Radiation Safety.

You may also be interested in reading Matthew's firsthand account of how he and Blake built their first X-ray machine and began their adventures in radiation experimenting: Science (and Radiation Experiments) as a Summer Hobby.

Bibliography

  • American Nuclear Society. (2011, July 22). Radiation Dose Chart. Retrieved September 27, 2011.
  • United States Center for Disease Control. (2011, March 30). Radiation and Your Health. Retrieved September 27, 2011.
  • United States Environmental Protection Agency. (2010, July 19). RadTown USA. Retrieved September 27, 2011.
  • United States Nuclear Regulatory Committee. (2011, September 8). Units of Radiation Dose. Retrieved September 27, 2011.
  • United States Occupational Safety and Health Administration. (2011). Radiation. Retrieved September 27, 2011.

Materials and Equipment

This X-ray machine can be assembled for as little as $300, assuming you borrow a Geiger counter for safety purposes. The table below lists the materials needed to build the X-ray machine. Make sure to read through the entire project and the Introduction to Radiation & Radiation Safety page before purchasing the materials. This will help you make informed decisions about the type of radiation shielding you choose to purchase as well as other optional materials.

Part Name Purpose Cost Estimate Vendor Option (s) Notes
X-ray tube Machine part $55 (large) United Nuclear
High-voltage power supply Machine part $180 United Nuclear The power supply must produce a minimum of 20,000 DC volts (20kV). A variable high voltage power supply, capable of producing >20kV in adjustable increments, is better.
Electrical tape Machine part <$5 Local hardware or home-construction store To connect the power supply to the X-ray tube.
Alligator clips (5). Five are needed for the vacuum tubes listed above; other brands may need more or less. Machine part <$10 Jameco Electronics To connect the power supply to the X-ray tube.
12 AWG hookup wire, 8 feet minimum Machine part <$10 Hardware store To connect the power supply to the X-ray tube.
Rubber or styrofoam to use as insulating material Machine part <$10 Local hardware or home-construction store To keep wire away from any metal objects that may cause arcing.
Fan; most any tabletop style 6-7 inch fan will do. Machine part $20 Holmes Blizzard Fan

Local hardware or department store
To prevent the X-ray tube from overheating by circulating air inside the shielding.
Wooden boards, Nail or screws, Velcro Mounting <$20 each Local hardware or home-construction store To create a mounting platform for the X-ray machine. See Figure 3 below.
Radiation shielding Machine part and safety Lead sheets (variable cost) United Nuclear

Nuclead
Lead (as either sheets or bricks) is the most common radiation shielding material. For this machine it is recommended you encase most of the X-ray tube (see Machine Assembly below for details) with a 1.2 inch thick wall of lead. Students may be able to borrow lead shielding from school or another local laboratory.
Lead bricks (variable cost) Nuclead
Concrete bricks (variable cost; least expensive option) Local hardware or home-construction store Concrete is a cheaper but effective alternative to lead shielding. For this machine it is recommended you encase most of the X-ray tube (see Machine Assembly below for details) with a 7.2 inch thick wall of solid concrete.
Geiger counter Machine testing and safety $160 Geiger Counter Essential for safety and testing the machine. The counter should be able to measure gamma and X-rays. Students may be able to borrow one from school or a local lab.

Experimental Procedure

Assembling the X-ray Machine

  1. Before building the X-ray machine, make sure you have read and understand all the background information in the Introduction to Radiation & Radiation Safety. If you are building this to use for a science fair you may need prior approval. Check with your science fair rules carefully and read our guide to regulations for Projects Involving Hazardous Chemicals, Activities, or Devices.
  2. Review Figure 1 below which shows that an X-ray machine is made up of three main parts: a high-voltage power supply that is hooked up to an X-ray tube with shielding around the X-ray tube for safety purposes.
Simple circuit diagram of a battery connected to a shielded X-ray tube
Figure 1. The diagram shows the three main parts of a homemade X-ray machine: a high voltage power supply, an X-ray tube, and shielding for safety.

Safety Check
A high voltage symbol

This X-ray machine requires you to hook up and use a high-voltage power supply. Exercise extreme caution when doing so. Accidental contact with high voltage supplying sufficient energy can result in severe injury or death. Furthermore, 20kV of electricity (which is the minimum supplied by the power supply in this project) can easily jump several inches, so do not allow anyone to touch or even come close (less than 8 inches) to the wires, alligator clips, or terminals on the X-ray tube while the power supply is on. A person's body can provide a path for current flow causing tissue damage and heart failure. Other injuries can include burns from the arc generated by the accidental contact.

  • Make sure the wires are properly connected and that you are not operating the power supply close to water or with wet hands.
  • Before plugging in the power supply, make sure that the alligator clips are securely held in place using the electrical tape.
  • Other than the on/off button, do not handle or be closer than 8 inches to the power supply, attached wires, alligator clips, or terminals on the X-ray tube while the power supply is plugged in.
  • Because there is a fire hazard risk related to high voltage wires, make sure that the wires between the power supply terminals and the X-ray terminals are short, hanging in the air, and not close to anything. If there is any metal nearby, such as nails in the floor, uninsulated lead shielding, or another wire, the high voltage may arc through the wires to the metal, possibly melting the insulation on the wires and catching them on fire, along with whatever was being arced to (such as the floor).
A radiation symbol

X-rays are a form of ionizing radiation and can cause permanent tissue damage and illness if you are exposed to too much. Read the Introduction to Radiation & Radiation Safety guide before building and operating this X-ray machine.

  • Never operate the X-ray machine without proper shielding.
    • This includes shielding above the machine if you are on the first floor of a multi-story building with people above you, and shielding below the machine if you are in a building with people on floors below you.
  • Use a Geiger counter to keep track of the radiation levels every time you operate the machine.
  • If the Geiger counter readings outside of the shielding exceed 300 microrem (μRem) per hour, turn the machine off immediately and work on increasing the shielding.
  1. Using alligator clips and 12 gauge (American Wire Gauge, AWG) hookup wire, connect the power supply to the X-ray tube.
    1. Warning: Do not plug in or turn on the power supply until it is all properly connected and the radiation shielding is in place. When working with the high voltage power supply, remember that the output can be deadly if mishandled.
    2. Make sure that you connect the X-ray tube in the right orientation. Because there is a positive end and a negative end to the tube (see Figure 2), connect the power supply so that current flows in the correct direction. Connect the positive output of the power supply to the tip of the tube and the negative end of the power supply to the base pins of the tube as shown in Figure 2.
    3. Note: Size 10 AWG wire will also work for making these connections. The size 10 and 12 AWG are both lower gauge wires, which are thicker, and thus better for higher voltages like the ones outputted by this power supply.
    4. Once the alligator clips are connected to the X-ray tube correctly, wrap electrical tape around the alligator clips and X-ray tube to secure the alligator clips in place.
Attaching alligator clips to an X-ray tube
Figure 2. Pay close attention to make sure the alligator clips attach the negative end of the X-ray tube to the negative end of the power supply and the positive end of the X-ray tube to the positive end of the power supply. Once they are in place, secure the alligator clips using electrical tape.
Connecting X-ray tube and power supply with alligator clips
Figure 3. Connect the X-ray tube and power supply with alligator clips and hookup wire. To contain your setup you may find it easiest to build a wooden platform, like the one shown here, for your X-ray machine.
  1. Next, organize the placement of the power supply and the tube. There are two options:
    1. Option 1: Mount the power supply and X-ray tube on a wooden board as shown in Figure 3.
      1. This option allows the X-ray machine to be easily transported and is the option we will continue to depict in subsequent images.
      2. Mount the power supply using Velcro; secure the X-ray tube by feeding the attached wires though slots in the wooden mount.
    2. Option 2: Hide everything in some sort of container. The exact dimensions of the container depend on the size of the power supply that you use, as well as what you're going to use the X-ray machine for (and thus which parts you need access to often), but it is a neat way to keep everything out of sight and organized.
      1. Caution: In this design, the X-ray tube is more likely to overheat, so make sure to include an opening for a cooling fan.
      2. Dangerouslaboratories.com has an example of an X-ray machine housed in an old toolbox.
  2. Set up the shielding material around the X-ray tube. This step is critical for the safe operation of the X-ray machine. Depending on what material you're using and what you intend to do with the machine, you will have to place shielding in different ways around the tube. Regardless of what you do with the shielding, keep an opening somewhere on the shield for ventilation and cooling. Review the Introduction to Radiation & Radiation Safety document before making decisions about shielding.
    1. Shielding material: Lead and concrete are the two options for materials that are safe to use for shielding.
      1. Lead shielding: Lead is the traditional shielding material. It has a halving thickness of 0.4 inches (refer back to the Information about Radiation and Radiation Safety document for a discussion of what this means). To guarantee safety in this setup, there must be three halving thicknesses around the X-ray tube. This corresponds to a 1.2 inch thick enclosure of lead. Lead is the thinnest reliable shielding material and thus takes up the least amount of room, but it is much more expensive than concrete.
      2. Concrete shielding: You can also use concrete to effectively shield from X-rays. It has a halving thickness of 2.4 inches. To guarantee safety in this setup, there must be three halving thicknesses around the X-ray tube. This corresponds to a 7.2 inch thick enclosure of concrete. If you are using concrete, one of the cheapest means is to buy solid concrete blocks and use them to build a wall or dome around the tube. Make sure the blocks are solid concrete.
    2. Placement of the shielding. Exactly where you place the shielding depends on what you plan to do with the X-ray machine. As shown in Figure 4, the shielding always needs to be placed between the X-ray tube and the power supply, so anyone turning the power supply on and off is not exposed to radiation.
      1. If you want to irradiate objects or organisms in close proximity to the tube, you might want to shield the entire tube, leaving no openings (except the one for ventilation). You can form a concrete igloo around the tube with concrete bricks, or use lead sheets to completely cover the tube. This will keep the X-rays in the area enclosed by the shielding, as long as there is no opening in the material. Be sure to leave enough room for your sample (the object or organisms you want to irradiate) within the shielding enclosure.
      2. If you want to develop images with the X-rays, you should leave an opening in the side or top of the shielding so that a controlled stream of X-rays can escape for the imaging exposure. This opening should never be pointed toward where the machine user might stand or other people might walk by.
      3. If the X-ray machine is on a table, or on the floor of a multi-story building, you must put shielding below the X-ray machine. Similarly, if you are in a multi-story building with people above you, you must put shielding above the X-ray machine.
Lead shielding wrapped in plastic surrounds an X-ray tube on three sides
Figure 4. In this experimental setup the lead shielding (wrapped in plastic for convenience) surrounds the X-ray tube on three sides. An opening in the shielding in the top allows ventilation and prevents overheating. The back is open as this particular machine was designed to be placed against a concrete wall during use. This machine was used in a one-story building, so it did not need shielding above or below it.
  1. Because there is a fire hazard related to high voltage wires, make sure that the wires between the power supply terminals and the X-ray terminals are short, hanging in the air, and not close to anything (including lead shielding, another wire, and any metal in the floor, such as nails). Keep the lead insulated from the wires with some Styrofoam or rubber.
    1. Safety note: High voltage wires will try to arc to metal, and the insulation on the wires will not stop arcing. If there is any metal nearby, such as nails in the floor, uninsulated lead shielding, or another wire, the high voltage may arc through the insulation and to the piece of metal, possibly melting the insulation and catching the wires on fire, along with whatever was being arced to (such as the floor).
  2. Place a fan inside the shielding area so that it can move air around and out of the shield through the ventilation opening. This is very important, since the X-ray tube builds up heat that can interfere with the samples that you may be irradiating and can decrease the life of the tube. The fan will keep the temperature fairly constant and relatively cool.
  3. Find an appropriate place to use the machine. Try to place the machine in the corner of a room, ideally bordered by thick walls that can absorb radiation. Always test and calibrate the X-ray machine before use, as will be covered next in this guide.

Testing the Machine

Now that the machine has been built, you need to make sure that it actually works and that the shielding is sufficient. It is simple and safe to test whether the machine works and also to check for any problems. When using the X-ray machine, it is a good idea to post signs asking others to stay out of the room and to make sure that all pets and young children are also out of the room.

  1. Make sure that the X-ray machine is unplugged and turned off. Turn on the Geiger counter. Record what the normal background radiation reading is.
  2. Next you will want to test the radiation reading when the X-ray machine is on from behind the shielding, standing where the "Experimenter" is labeled in Figure 5 below. This will let you make sure that the shielding is sufficient to protect you while you complete the rest of the X-ray machine testing and calibrating steps.
    1. Turn on the fan.
    2. Stand away from the opening in the shielding, plug in the power supply, and turn it to 30,000 volts (30kV). At this point the machine is active and dangerous and is producing X-rays.
      1. Safety note: Other than the on/off button on the power supply, do not handle or be closer than 8 inches to the power supply, attached wires, alligator clips, or terminals on the X-ray tube while the power supply is plugged in. 30kV of electricity can easily jump several inches, and accidental contact could result in severe injury or death.
    3. Standing behind the shielding, where the "Experimenter" is labeled in Figure 5 below, hold the Geiger counter in your hand and take a radiation reading. Any Geiger counter readings above 300 microrem (µRem) per hour outside of the shielding is cause for concern. If you see such a reading, turn the machine off immediately and work on increasing the shielding. Even if the Geiger counter readings are below 300 µRem per hour, you may still want to increase the shielding. It depends on your total exposure. Read "Calibrating the X-ray Machine" below for more details.
  3. When you are done checking your shielding, turn off the power supply and unplug it.
Lead shielding is tested by holding a Geiger counter behind a lead shield while an X-ray tube is turned on
Figure 5. To test that your shielding is working, turn on the X-ray machine and stand safely behind the shielding (the place labeled "Experimenter" in this image) with the Geiger counter in your hands.
  1. Then, making sure the Geiger counter is still on, place it anywhere from 6 inches to 2 feet from the opening in the machine shielding so that you can read it from a safe vantage point. The idea here is to use the Geiger counter to see whether the machine is outputting X-rays after you turn it back on. You should not hold on to the Geiger counter during this test; instead devise a way to put it down but still read it from behind the shielding as diagramed in Figure 6 below.
An X-ray tube is tested by holding a Geiger counter above a powered on X-ray tube from behind a lead shield
Figure 6. To test that the X-ray machine is working, place a Geiger Counter a few inches from an opening in the shielding (a shelf above the ventilation opening would work) with the display face of the Geiger counter visible from a safe distance. The experimenter should stand safely behind the shielding, but still be able to read the Geiger counter.
  1. Turn on the fan.
  2. Stand away from the opening in the shielding, plug in the power supply, and turn it to 30kV. At this point, the machine is active and dangerous and is producing X-rays. The Geiger counter should be getting a reading.
    1. Safety note: Other than the on/off button on the power supply, do not handle or be closer than 8 inches to the power supply, attached wires, alligator clips, or terminals on the X-ray tube while the power supply is plugged in.
  3. Observe the reading on the Geiger counter. From the moment that the X-ray machine is turned on, the Geiger counter should have a much higher reading than normal. If it has audio features, it might begin beeping much more than usual. This indicates that the machine is working.
    1. Make sure you have tested what normal background readings are before you turn on the X-ray machine.
    2. If you were to place the Geiger counter right next to the vacuum tube (inside the shielding) while it is running, the counter could max out.
    3. Safety note: Radiation safety is usually thought of in terms of overall dose over time as opposed to an immediate exposure value. However, any Geiger counter readings above 300 microrem (μRem) per hour outside of the shielding is cause for concern. Turn the machine off immediately and work on increasing the shielding.
  4. When you are all done with your X-ray machine project, if you used lead shielding, you should not throw it away. You should recycle it instead. Check with local recycling centers to see if they accept lead.

Troubleshooting After the First Test

During the testing of the machine, you might encounter some problems. Here are a few, along with possible solutions.

  1. Arcing—arcing (the visible jump of electrical current from one component to another) might occur either between the wires and some metal that you have nearby or between the wires themselves. Make sure that the wires are separated from each other and that they aren't near any other metal, including nails in the floor, or lead, if you are using that as shielding. Keep the lead insulated from the wire with some Styrofoam or rubber. Arcing can melt the insulation on the wires and cause it to catch fire, along with anything it is arcing to.
  2. No change in the Geiger counter reading—if the Geiger counter doesn't detect any radiation when the power supply is turned on, there's probably an issue with the wiring between the power supply and the X-ray tube. Turn off the power, unplug the power supply, and check that the polarity of the tube is correct (that it's oriented the right way for current to flow through it) and that the power supply is working correctly. Other possible problems include:
    1. The power supply might be missing a fuse, it might not be plugged in, or it might not be outputting enough voltage.
    2. The X-ray tube itself could be faulty.
    3. The Geiger counter could also be the problem, since it might not be able to detect gamma rays or X-rays.
    4. Check all of these things if you think there is a problem with the machine's ability to produce X-rays.
    5. After you get the X-ray machine working, be sure to re-test the shielding for radiation leaks (as described in the Testing the Machine section above, in step 2).

Calibrating the X-ray Machine

Now that the machine is working, you need to find out how much radiation it can output. You will need to find approximate exposure values at different areas in order to get an idea of your safety and the capability of the machine. Generally, the output energy of the X-rays is correlated directly to the input energy from the power supply. So 1 V of input energy should output 1 eV (electron volt) of X-ray energies. X-ray tubes can generally maintain this 1:1 ratio of input to output energy; the main difference among tubes is in the amount, or intensity, of X-rays produced. The calibration procedure is to determine the intensity of the X-rays in terms of exposure, as measured by a Geiger counter. You will make a table of values that you can refer back to for safety reasons and for radiation calculations later.

  1. Make sure that the machine is turned off and unplugged. Place the Geiger counter 2 feet away from the X-ray tube, in line with the opening in the shielding. Turn on the Geiger counter.
  2. Turn on the fan. Stand away from the opening in the shielding, plug in the power supply, and turn it to 20kV. Observe and record the reading on the Geiger counter.
    1. Safety note: Other than the on/off button on the power supply, do not handle or be closer than 8 inches to the power supply, attached wires, alligator clips, or terminals on the X-ray tube while the power supply is plugged in.
  3. Repeat for various input voltages, such as 20kV, 30kV, 40kV, and 50 kV.
  4. Also repeat for various locations, such as at the power supply location, at your head level when you operate the machine, and at points throughout the area that you work in. Be sure to turn off the machine (i.e., turn off the power supply and unplug it) when you make any changes to the position of the Geiger counter.
  5. After testing you should have a table of values similar to Table 1 below.
Power Supply Voltage Geiger Reading at Each Location
Two Feet from the X-ray Tube Power Supply Head Level Far Corner of Room Right Next to Shielding
20 kV       
30 kV       
40 kV       
50 kV       
60 kV       

Table 1. During calibration you will make a table, similar to this one, of Geiger readings at various locations around the X-ray machine at different voltages.

  1. The table of values should be sufficient to determine the radiation potential of the machine. If you are irradiating samples, then you can use this procedure to determine their exposure based on distance from the tube. Otherwise, this is useful as a benchmark for safety when using the machine.
  2. Safety notes:
    1. Radiation safety is usually thought of in terms of overall dose as opposed to an immediate exposure value. However, any Geiger counter readings above 300 μRem per hour outside of the shielding is cause for concern. Turn the machine off immediately and work on increasing the shielding.
    2. With radiation the answer is usually the less the better. Here are a couple of facts to keep in mind.
      1. A single chest X-ray or dental X-ray, both of which are considered to be medically safe, exposes a patient to 10 mrem of radiation. Limiting your exposure for a single experiment to 10 mrem would be similar to getting an X-ray.
      2. The international safety standard is 5,000 mrem or less per year. Your annual exposure, both normal and experimental, should fall below the 5,000 mrem level.
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Ask an Expert

Do you have specific questions about your science project? Our team of volunteer scientists can help. Our Experts won't do the work for you, but they will make suggestions, offer guidance, and help you troubleshoot.

Global Connections

The United Nations Sustainable Development Goals (UNSDGs) are a blueprint to achieve a better and more sustainable future for all.

This project explores topics key to Good Health and Well-Being: Ensure healthy lives and promote well-being for all at all ages.

Variations

This x-ray machine can be used to conduct many different types of experiments. Here are a few ideas to get you started:

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Science Buddies Staff. "How to Build an X-ray Machine." Science Buddies, 15 Apr. 2023, https://www.sciencebuddies.org/science-fair-projects/project-ideas/Phys_p083/physics/how-to-build-an-x-ray-machine?class=AQWSfXY19h32SXcX1Wm9V_ERHa5kfSLXMbzOCheMLe6notaYoLQrGJLHEQbwjhettzTlbH0K8Qge1CkF253jZtlHG-5m2cbsR4bDxMZELCs5qg. Accessed 19 Mar. 2024.

APA Style

Science Buddies Staff. (2023, April 15). How to Build an X-ray Machine. Retrieved from https://www.sciencebuddies.org/science-fair-projects/project-ideas/Phys_p083/physics/how-to-build-an-x-ray-machine?class=AQWSfXY19h32SXcX1Wm9V_ERHa5kfSLXMbzOCheMLe6notaYoLQrGJLHEQbwjhettzTlbH0K8Qge1CkF253jZtlHG-5m2cbsR4bDxMZELCs5qg


Last edit date: 2023-04-15
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