Van de Graaff Generator Diagram

Van de Graaff Generator Main Parts

The classic Van de Graaff generator, named “Van de Graaff” in honor of his inventor, is a machine to produce high voltage potentials using the physics principle of friction: two different materials in close contact produces an electron exchange between then, originating a voltage potential. The Van de Graaff generator is such a machine that makes this process practical, not only generating the potential by friction in a continuous way but also providing an efficient form of amplification and accumulation of the electrical charge generated. To achieve this goal a Van de Graaff electrostatic machine is composed by the following key parts:

Van de graaff diagram
Innovationview: Van de graaff diagram


  • A charge conveyor belt
  • An upper and lower roller
  • An upper and lower comb
  • A hollow metallic sphere

The belt

The belt is one the most important van de graaff generator parts, its function is to transport the electric charge produced with the lower roller to the upper part of the Van de Graaff electrostatic machine. The Van de Graaff belt should be made of a non conductive material, because the electric charges are transported mechanically and must stay “bounded” to the belt surface. A Van de Graaff generator don´t need to be vertical, in fact this position is chosen because the extremities of the machine need to be kept apart, and with a horizontal structure can be more difficult to maintain that isolation.

The lower roller

On lower roller the primary charges are produced, the lower roller and the belt correspond to different positions in the triboelectric series, what means that the materials that composes these parts on the Van de Graaff generator has different ability to gain or loose electrons. Ideally the lower roller should be mad with a material that is in an extremity of the triboelectricity series, the belt are in the middle and the upper roller are in the opposite extreme. To simplify we can say that the friction between the roller and the belt produces an exchange of electric charge, in fact, is not the friction between the materials, but just the close contact between them, the different ability to gain or loose electrons is that produces the electrostatic interaction providing electrons exchange. As result the belt exhibit an opposite charge related to the roller, as the belt is rolling it carries away the charge to the upper part of Van de Graaff machine, but on roller the charge stays concentrated.

The lower comb

The lower comb transfer charges from an charge source to the belt, the concentrated charge on lower roller attracts opposite charge from the lower comb that has a sharp ends and is connected to the earth, an infinite source of charge. The charges forms a plasma that fills the gap between the comb extremity and the belt, this enable that more charge are deposited over the belt, as they are attracted to the lower roller. In a practical Van de Graaff generator the lower comb is connected to the machines structure,that provides the charges for machine operation.

The upper roller

This roller is situated inside the metallic hollow sphere and also interacts with the belt for charge generation. When the charged belt encounters the upper roller, due to the triboelectric difference the upper roller will be charged with a polarity which has the same polarity that the belt initially have, also some opposed charge are created over the belt what neutralizes few initial charge. The electric charge concentrated on the upper roller repel the initial charge on belt and attracts opposite charge from the upper comb.

The upper comb

Made of a conductive material, this element is responsible to make possible the charge exchange between the belt and the metallic sphere, it has a sharp end that forms a small gap with the belt and is connected with the inner part of the sphere. In the same way that the lower comb, the sharp end creates a high potential difference to the roller producing an air ionization around it. Is the ionized air that makes possible the charges to move from the metallic sphere, that is electrically connected with the upper comb, in direction to the roller. As the charges travels toward the upper roller it encounters the belt midway and interacts with the charges already on it neutralizing the belt electric balance and enabling the process to start again. As result of this charge exchange processes the metallic sphere on top of Van de Graaff generator retain some electric charge.

The metallic hollow sphere

Is the hollow metallic sphere that stores the charge that is generated on Van de Graaff generator, these charges are transferred to it by means of the upper comb. When the charge arrives at the sphere, it tends to migrate to his external surface, because of the electric repulsion among then. The charge are injected continually while generator is running and grows until it reaches an electrical potential high enough to break the air isolation. When an electrical conductor object is put near the charged sphere, if it is close enough, the electric barrier is broken and a bright and thunderous spark is produced. The distance from the sphere that the spark begins is an indicating on how much charged was the sphere, also the sphere should not have any sharp edges because if they exist the charges will not be accumulated properly as small sparks will appear around the edges discharging the sphere.


Van de graaff Generator

Van de Graaff generator of the first Hungarian linear particle accelerator showing the transport belt,
the sphere in this case is replaced by a hollow metallic structure with round edges.
By Zátonyi Sándor, (ifj.) (Own work) [GFDL or CC-BY-SA-3.0], via Wikimedia Commons

Now that you know the main Van de Graaff Generator parts, why not build yourself a Van de Graaff generator that can be hand operated requiring no electricity or batteries? Get the DIY plans here at

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