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Raised Floor Supporting Structure Used as a Signal Reference Grid
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the safety ground, but augments the safety ground for noise reduction
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Add a transient suppression plate at or near the power entry point (with the power cabling laid on top of it) to provide a controlled capacitive and magnetic coupling noise bypass between building reinforced steel and the electrical ground conductors
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1059 Summary of wiring and grounding solutions
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The grounding system should be designed to accomplish these minimum objectives: 1 There should never be load currents flowing in the grounding system under normal operating conditions One can likely measure very small currents in the grounding system due to inductive coupling, capacitive coupling, and the connection of surge suppressors and the like In fact, if the ground current is exactly zero, there is probably an open ground connection However, these currents should be only a tiny fraction of the load currents 2 There should be, as near as possible, an equipotential reference for all devices and locations in the system 3 To avoid excessive touch potential safety risks, the housings of all equipment and enclosures should be connected to the equipotential grounding system
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Wiring and Grounding 454 Ten
The most important implications resulting from these objectives are: 1 There can only be one neutral-to-ground bond for any subsystem A separately derived system may be created with a transformer, which establishes a new neutral-to-ground bond 2 There must be sufficient interconnections in the equipotential plane to achieve a low impedance over a wide frequency range 3 All equipment and enclosures should be grounded
106 Bibliography In addition to the standard reference books cited early, the following books are recommended for further reading on this subject:
Hasse, P, Overvoltage Protection of Low Voltage Systems, IEE Power Series 12, Peter Peregrinus, Ltd, London, 1992 Mardiguian, Michael, A Handbook Series on Electromagnetic Interference and Compatibility, Vol 2, Grounding and Bonding, Interference Control Technologies, Inc, Gainesville, Va, 1988 Morrison, Ralph, and Warren H Lewis, Grounding and Shielding for Facilities, John Wiley & Sons, New York, 1990 Ott, Henry W, Noise Reduction Techniques in Electronic Systems, 2d ed, John Wiley & Sons, New York, 1988
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Source: Electrical Power Systems Quality
Power Quality Monitoring
Power quality monitoring is the process of gathering, analyzing, and interpreting raw measurement data into useful information The process of gathering data is usually carried out by continuous measurement of voltage and current over an extended period The process of analysis and interpretation has been traditionally performed manually, but recent advances in signal processing and artificial intelligence fields have made it possible to design and implement intelligent systems to automatically analyze and interpret raw data into useful information with minimum human intervention Power quality monitoring programs are often driven by the demand for improving the systemwide power quality performance Many industrial and commercial customers have equipment that is sensitive to power disturbances, and, therefore, it is more important to understand the quality of power being provided Examples of these facilities include computer networking and telecommunication facilities, semiconductor and electronics manufacturing facilities, biotechnology and pharmaceutical laboratories, and financial data-processing centers Hence, in the last decade many utility companies have implemented extensive power quality monitoring programs In this chapter, various issues relating to power quality monitoring are described Section 111 details the objectives and procedures for performing monitoring Section 112 provides historical perspective on various monitoring instruments Section 113 provides a description of various power quality monitoring instruments and their typical functions Section 114 describes methods of assessment of power quality data Section 115 details the applications of intelligent systems in automating analysis and interpretation of raw power quality measurement data Section 116 reviews standards dealing with power quality monitoring
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