The ESD Control Program Handbook. Jeremy M. Smallwood. Читать онлайн. Newlib. NEWLIB.NET

Автор: Jeremy M. Smallwood
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Техническая литература
Год издания: 0
isbn: 9781118694558
Скачать книгу
rel="nofollow" href="#ulink_ed2cf545-e55a-59e3-9acd-b59ee04d57dd">Figure 1.3).

      The volume resistance Rv measured through a material of volume resistivity ρv using electrodes of area A is given by

equation

      where t = A = 1, or t/A = 1, which reduces to ρv = Rv.

      The unit of volume resistivity is ohm meter (Ωm). The volume resistivity of a material is often simply referred to as its resistivity.

      In practice, standards exist for measuring volume resistivity using concentric ring electrodes (IEC 62631‐3‐1 (International Electrotechnical Commission 2016c), IEC 61340‐2‐3 (International Electrotechnical Commission 2016b), ANSI/ESD STM 11.12 (EOS/ESD Association Inc. 2015b))

Schematic illustration of the definition of volume resistivity described with the resistance meter.

      The conductivity, σ, of the material is simply the inverse of its resistivity.

equation

      The units of conductivity are siemens per meter (Sm−1).

      The resistivity of materials can vary by many orders of magnitude from 10−8 Ωm (e.g. copper) to more than 1015 Ωm (e.g. mica, quartz, polytetrafluoroethylene, polyethylene).

      1.7.3 Insulators, Conductors, Conductive, Dissipative, and Antistatic Materials

      There is no fundamental definition of insulators and conductors in electrostatics. In reality, there is a continuum of material resistivity from highly conducting (low resistance) to highly insulating (very high resistance). Different industry areas may have differing views on the resistance level at which a material is considered to have insulating properties.

      For our purposes, a conductor is a material that allows charge to move around on the surface or in the bulk of the material and can thereby be used to transport charge from one place to another. An insulator (nonconductor) is a material that does not allow the charge to move in this way.

      One problem in practice is that a material that is considered “insulating” in one application may be considered significantly conducting in electrostatics. So, for some years I have offered the following pragmatic definitions for use in practical electrostatics and ESD control:

       A conductor is a material that allows charge to move away quickly enough to avoid significant electrostatic charge build up.

       An insulator is any material that is not a conductor, in other words, a material that does not allow charge to move quickly enough to avoid charge build up.

      Conductors are easily maintained at a low voltage by connecting them to earth (ground). However, an insulator in electrostatic terms cannot be maintained at a low voltage by installing a ground connection. The charge on the material simply does not move to the ground connection quickly enough to be conducted away in the desired timescale.

      Materials or equipment are often defined as conductors or insulators based on either their measured resistance or a charge decay time. This is discussed further in Chapter 2.

Term Application General use Meaning under 61340‐5‐1:2016a Meaning under S20.20‐2014
Conductive General Resistance <106 Ω Not defined Not defined
ESD control footwear Not defined Not defined
ESD control flooring <106 Ω Not defined Not defined
ESD protective packaging Surface resistance <104 Ω Surface and volume resistance <104 Ω
Static dissipative General Resistance between 106 and 1011 Ω Not defined Not defined
ESD control footwear Not defined Not defined
ESD control flooring ≥106 Ω Not defined Not defined
ESD protective packaging Surface resistance ≥104 and ≤1011 Ω Surface and volume resistance ≥104 and <1011 Ω
Insulative General Resistance over 1011 Ω Not defined Not defined
ESD control footwear Not defined, but by implication >108 Ω Not defined, but by implication resistance >109 Ω

e-mail: [email protected]