Radiated coupling: Difference between revisions
From Electrical Installation Guide
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{{Menu_EMC_guidelines}} | {{Menu_EMC_guidelines}}__TOC__ | ||
__TOC__ | == Definition == | ||
The disturber and the victim are coupled by a medium (e.g. air). The level of disturbance depends on the power of the radiating source and the effectiveness of the emitting and receiving antenna. An electromagnetic field comprises both an electrical field and a magnetic field. The two fields are correlated. It is possible to analyse separately the electrical and magnetic components | The disturber and the victim are coupled by a medium (e.g. air). The level of disturbance depends on the power of the radiating source and the effectiveness of the emitting and receiving antenna. An electromagnetic field comprises both an electrical field and a magnetic field. The two fields are correlated. It is possible to analyse separately the electrical and magnetic components. | ||
The electrical field (E field) and the magnetic field (H field) are coupled in wiring systems via the wires and loops (see {{FigRef|R37}}). | |||
{{FigImage|DB422803_EN|svg|R37|Definition of radiated coupling}} | |||
When a cable is subjected to a variable electrical field, a current is generated in the cable. This phenomenon is called field-to-cable coupling. | When a cable is subjected to a variable electrical field, a current is generated in the cable. This phenomenon is called field-to-cable coupling. | ||
Similarly, when a variable magnetic field flows through a loop, it creates a counter electromotive force that produces a voltage between the two ends of the loop. This phenomenon is called field-to-loop coupling. | |||
(see | == Examples == | ||
(see {{FigRef|R38}}) | |||
*Radio-transmission equipment (walkie-talkies, radio and TV transmitters, mobile services) | *Radio-transmission equipment (walkie-talkies, radio and TV transmitters, mobile services) | ||
| Line 26: | Line 24: | ||
*Lighting | *Lighting | ||
{{FigImage|DB422804_EN|svg|R38|Examples of radiated coupling}} | |||
== Counter-measures == | |||
To minimise the effects of radiated coupling, the measures below are required. | To minimise the effects of radiated coupling, the measures below are required. | ||
=== For field-to-cable coupling === | |||
*Reduce the antenna effect of the victim by reducing the height (h) of the cable with respect to the ground referencing plane | *Reduce the antenna effect of the victim by reducing the height (h) of the cable with respect to the ground referencing plane | ||
| Line 44: | Line 38: | ||
*Place filters or ferrite rings on the victim cable | *Place filters or ferrite rings on the victim cable | ||
=== For field-to-loop coupling === | |||
*Reduce the surface of the victim loop by reducing the height (h) and the length of the cable. Use the solutions for field-to-cable coupling. Use the Faraday cage principle. | *Reduce the surface of the victim loop by reducing the height (h) and the length of the cable. Use the solutions for field-to-cable coupling. Use the Faraday cage principle. | ||
Radiated coupling can be eliminated using the Faraday cage principle. A possible solution is a shielded cable with both ends of the shielding connected to the metal case of the device. The exposed conductive parts must be bonded to enhance effectiveness at high frequencies. | Radiated coupling can be eliminated using the Faraday cage principle. A possible solution is a shielded cable with both ends of the shielding connected to the metal case of the device. The exposed conductive parts must be bonded to enhance effectiveness at high frequencies. | ||
Radiated coupling decreases with the distance and when symmetrical transmission links are used. | |||
Latest revision as of 09:49, 22 June 2022
Definition
The disturber and the victim are coupled by a medium (e.g. air). The level of disturbance depends on the power of the radiating source and the effectiveness of the emitting and receiving antenna. An electromagnetic field comprises both an electrical field and a magnetic field. The two fields are correlated. It is possible to analyse separately the electrical and magnetic components.
The electrical field (E field) and the magnetic field (H field) are coupled in wiring systems via the wires and loops (see Fig. R37).
Fig. R37 – Definition of radiated coupling
When a cable is subjected to a variable electrical field, a current is generated in the cable. This phenomenon is called field-to-cable coupling.
Similarly, when a variable magnetic field flows through a loop, it creates a counter electromotive force that produces a voltage between the two ends of the loop. This phenomenon is called field-to-loop coupling.
Examples
(see Fig. R38)
- Radio-transmission equipment (walkie-talkies, radio and TV transmitters, mobile services)
- Radar
- Automobile ignition systems
- Arc-welding machines
- Induction furnaces
- Power switching systems
- Electrostatic discharges (ESD)
- Lighting
Fig. R38 – Examples of radiated coupling
Counter-measures
To minimise the effects of radiated coupling, the measures below are required.
For field-to-cable coupling
- Reduce the antenna effect of the victim by reducing the height (h) of the cable with respect to the ground referencing plane
- Place the cable in an uninterrupted, bonded metal cableway (tube, trunking, cable tray)
- Use shielded cables that are correctly installed and bonded
- Add PECs
- Place filters or ferrite rings on the victim cable
For field-to-loop coupling
- Reduce the surface of the victim loop by reducing the height (h) and the length of the cable. Use the solutions for field-to-cable coupling. Use the Faraday cage principle.
Radiated coupling can be eliminated using the Faraday cage principle. A possible solution is a shielded cable with both ends of the shielding connected to the metal case of the device. The exposed conductive parts must be bonded to enhance effectiveness at high frequencies.
Radiated coupling decreases with the distance and when symmetrical transmission links are used.
