Jeremy M. Smallwood

The ESD Control Program Handbook


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(e.g. track or component pin) on the charged board touches a highly conductive machine part (e.g. stop pin), a charged board ESD event can occur (Figure 2.17). The PCB can have high effective capacitance, so this type of discharge can be quite energetic.

      2.6.5 ESD from a Charged Module

      Many products, modules, or subassemblies have an insulating plastic housing containing a circuit board. The connections to this may be brought out to terminations at flying leads or a connector.

Graphs depict the ESD waveform from a printed circuit board (above) charged to 1 kV (below) field induced charged by insulator 40 mm away. Graph depicts the ESD waveform from a charged automotive module taken out of a polythene bag. Charge transferred 35 nC. Graph depicts the Voltage on an automotive cable core as polythene packaging is removed.

      2.6.6 ESD from Charged Cables

      At the heart of any ESD source is charge build‐up and storage. This is represented by the capacitance in the model C. In many cases in real life, this charge storage may be on a conductor (e.g. metal item).

Graphs depict the ESD waveform from a charged automotive wiring loom cable lying against an earthed metal plate. Positive (above) and negative (below) charging polarity. Schematic illustration of the electronic model of a simple ESD source.

      The discharge is usually initiated by a breakdown of an air gap or some other insulating medium. At low voltages, it can also be initiated by contact or near‐contact between two conductors. The discharge can itself have significant impedance RESD that can affect the waveforms produced and the energy delivered into the victim device. Often, however, this is negligible compared to the other impedances in the circuit, especially for larger ESD events.

      In the case of ESD to a victim device, the device also has impedance, modeled in this simple circuit by a resistance Rd. In practice, a nonlinear impedance would be more typical of a semiconductor device. The impedance of the spark channel is highly variable and nonlinear.

      For simplification, the total circuit resistance R is assumed to be linear and is the sum of the circuit resistances.

equation

      The discharge current IESD of this circuit has the form

equation

      For derivation of the equations for this and the following equations, the reader is referred to other texts (e.g. Agarwal and Lang 1987, https://en.wikipedia.org/wiki/RLC_circuit). This equation has two roots α, β given by

equation equation Graph depicts the simulated overdamped device current waveform IESD for dominant circuit resistance. equation

      Thereafter, the current drops nearly exponentially with decay time approaching RsCESD.

      At the other extreme, if the circuit resistance is insignificant compared to the inductive and capacitive impedance, the waveform is quite different. This occurs when

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