Choice of earthing method - implementation: Difference between revisions
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After consulting applicable regulations, | After consulting applicable regulations, {{FigureRef|E16}} and {{FigureRef|E17}} can be used as an aid in deciding on divisions and possible galvanic isolation of appropriate sections of a proposed installation. | ||
== Division of source == | == Division of source == | ||
This technique concerns the use of several transformers instead of employing one high-rated unit. In this way, a load that is a source of network disturbances (large motors, furnaces, etc.) can be supplied by its own transformer. | |||
The quality and continuity of supply to the whole installation are thereby improved. | |||
The cost of switchgear is reduced (short-circuit current level is lower). | |||
The cost-effectiveness of separate transformers must be determined on a case by case basis. | |||
The creation of galvanically-separated “islands” by means of LV/LV transformers makes it possible to optimise the choice of earthing methods to meet specific requirements (see | == Network islands == | ||
The creation of galvanically-separated “islands” by means of LV/LV transformers makes it possible to optimise the choice of earthing methods to meet specific requirements (see {{FigRef|E18}} and {{FigRef|E19}}). | |||
{{FigImage|DB422175_EN|svg|E18|TN-S island within an IT system}} | |||
{{FigImage|DB422176_EN|svg|E19|IT islands within a TN-S system}} | |||
== Conclusion == | == Conclusion == | ||
The optimisation of the performance of the whole installation governs the choice of earthing system. | |||
Including: | |||
*Initial investments, and | *Initial investments, and | ||
*Future operational expenditures, hard to assess, that can arise from insufficient reliability, quality of equipment, safety, continuity of service, etc. | *Future operational expenditures, hard to assess, that can arise from insufficient reliability, quality of equipment, safety, continuity of service, etc. | ||
An ideal structure would comprise normal power supply sources, local reserve power supply sources (see | An ideal structure would comprise normal power supply sources, local reserve power supply sources (see [[Selection criteria for the TT, TN and IT systems]] ) and the appropriate earthing arrangements | ||
[[ru:Выбор метода заземления и его реализация]] | [[ru:Выбор метода заземления и его реализация]] | ||
[[zh:接地方法的选用及其实施]] | [[zh:接地方法的选用及其实施]] | ||
Revision as of 08:08, 23 November 2016
After consulting applicable regulations, Figure E16 and Figure E17 can be used as an aid in deciding on divisions and possible galvanic isolation of appropriate sections of a proposed installation.
Division of source
This technique concerns the use of several transformers instead of employing one high-rated unit. In this way, a load that is a source of network disturbances (large motors, furnaces, etc.) can be supplied by its own transformer.
The quality and continuity of supply to the whole installation are thereby improved.
The cost of switchgear is reduced (short-circuit current level is lower).
The cost-effectiveness of separate transformers must be determined on a case by case basis.
Network islands
The creation of galvanically-separated “islands” by means of LV/LV transformers makes it possible to optimise the choice of earthing methods to meet specific requirements (see Fig. E18 and Fig. E19).
Conclusion
The optimisation of the performance of the whole installation governs the choice of earthing system.
Including:
- Initial investments, and
- Future operational expenditures, hard to assess, that can arise from insufficient reliability, quality of equipment, safety, continuity of service, etc.
An ideal structure would comprise normal power supply sources, local reserve power supply sources (see Selection criteria for the TT, TN and IT systems ) and the appropriate earthing arrangements
