MediaWiki:Eig-hierarchy: Difference between revisions
From Electrical Installation Guide
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**[[Focus on IEC 61557-12 standard]] | **[[Focus on IEC 61557-12 standard]] | ||
Revision as of 07:04, 16 October 2020
- General rules of electrical installation design
- Connection to the MV utility distribution network
- Power supply at medium voltage
- Procedure for the establishment of a new substation
- Protection against electrical hazards, faults and mis-operations in electrical installations
- The consumer substation with LV metering
- The consumer substation with MV metering
- Choice and use of MV equipment and MV/LV transformer
- Substation including generators and parallel operation of transformers
- Types and constitution of MV/LV distribution substations
- Connection to the LV utility distribution network
- MV and LV architecture selection guide for buildings
- Stakes of architecture design
- Simplified architecture design process
- Electrical installation characteristics
- Technological characteristics
- Architecture assessment criteria
- Choice of architecture fundamentals
- Choice of architecture details
- Choice of equipment
- Recommendations for architecture optimization
- Glossary
- Example: electrical installation in a printworks
- LV Distribution
- Protection against electric shocks and electrical fires
- Protection against electric shock
- Types of protection against electric shock
- Additional protection: High sensitivity RCDs
- Implementation of the TT system
- Implementation of the TN system
- Implementation of the IT system
- Residual Current Devices (RCDs)
- Other protective measures against electric shocks
- Protection against electrical fire risks
- Sizing and protection of conductors
- Conductor sizing and protection
- Practical method for determining the smallest allowable cross-sectional area of circuit conductors
- Determination of voltage drop
- Short-circuit current
- Short-circuit current at the secondary terminals of a MV/LV distribution transformer
- 3-phase short-circuit current (Isc) at any point within a LV installation
- Isc at the receiving end of a feeder as a function of the Isc at its sending end
- Short-circuit current supplied by a generator or an inverter
- Particular cases of short-circuit current
- Protective earthing conductor (PE)
- The neutral conductor
- Worked example of cable calculation
- LV switchgear: functions and selection
- Overvoltage protection
- Overvoltage of atmospheric origin
- Principle of lightning protection
- Design of the electrical installation protection system
- Design rules of the electrical installation protection system
- Elements of the protection system
- Common characteristics of SPDs according to the installation characteristics
- Selection of a Type 1 SPD
- Selection of a Type 2 SPD
- Selection of external Short Circuit Protection Device (SCPD)
- SPD and protection device coordination table
- Installation of Surge Protection Device
- Surge protection Application examples
- Surge protection technical supplements
- Energy Efficiency in electrical distribution
- Energy Efficiency in brief
- Energy efficiency and electricity
- Diagnosis through electrical measurement
- Energy saving opportunities
- Energy saving opportunities - Motors
- Energy saving opportunities - Lighting
- Energy saving opportunities - Power factor correction and harmonic filtering
- Energy saving opportunities - Load management
- Energy saving opportunities - Communication and information systems
- Energy saving opportunities - Smart Panels
- How to evaluate energy savings
- Power Factor Correction
- Power factor and Reactive power
- Why improve the power factor?
- How to improve the power factor?
- Where to install power factor correction capacitors?
- How to determine the optimum level of compensation?
- Compensation at the terminals of a transformer
- Power factor correction of induction motors
- Example of an installation before and after power-factor correction
- The effects of harmonics
- Implementation of capacitor banks
- Power harmonics management
- Characteristics of particular sources and loads
- Protection of a LV generator set and the downstream circuits
- Uninterruptible Power Supply units (UPS)
- Protection of LV/LV transformers
- Lighting circuits
- The different lamp technologies
- LED lighting - characteristics
- LED lighting - constraints and recommendations
- LED lamps - choice of circuit breaker
- LED lamps - choice of contactors
- Outdoor LED lighting
- Other lamp technologies - characteristics
- Other lamp technologies - constraints and recommendations
- Other lamp technologies - choice of contactors
- Other lamp technologies - choice of circuit breaker
- Lighting of building accessible to the public
- Asynchronous motors
- Motor control systems
- Motor protection functions
- Motor monitoring
- Motor starter configurations
- Motor protection coordination
- Basic motor protection scheme: circuit-breaker + contactor + thermal relay
- Control and protection switching gear (CPS)
- Intelligent Power and Motor Control Centre (iPMCC)
- Communication protocols and architectures in iPMCC
- PhotoVoltaic (PV) installation
- Trends and benefits of photovoltaic energy
- Photovoltaic background, technology
- PV System and Installation Rules
- Photovoltaic installation architectures
- Design of electrical installations integrating solar production
- Operation of installations integrating solar production
- Architectures for integration of solar production
- Calculation rules when integrating solar and storage
- Sizing of electrical installation with solar production and storage
- Specific protection of prosumer electrical installations
- Power quality - impact of solar self-consumption
- Power factor - impact of solar self-consumption
- Excess photovoltaic production - how to manage
- Monitoring and control of installations with solar production
- Residential premises and other special locations
- Residential electrical installation
- Residential electrical installation - The power network
- Residential electrical installation - Distribution boards components
- Residential electrical installation - Protection of people
- Residential electrical installation - Circuits
- Residential electrical installation - Protection against overvoltages and lightning
- Residential electrical installation - Periodic control
- Residential electrical installation - Requirements and recommendations for Kitchen
- Residential electrical installation - Requirements and recommendations for Living room
- Bathroom electrical installation
- Requirements applicable to special installations and locations
- Residential electrical installation
- ElectroMagnetic Compatibility (EMC)
- EMC behaviour of different electrical distribution architecturing
- EMC - Earthing principles and structures
- EMC implementation
- Equipotential bonding inside and outside buildings
- EMC implementation - Improving equipotential conditions
- EMC implementation - Separating cables
- EMC implementation - Raised floors
- EMC implementation - Cable running
- EMC implementation - Busway
- EMC implementation - Implementation of shielded cables
- EMC implementation - Communication networks
- EMC implementation - Implementation of surge arresters
- EMC implementation - Cabinet cabling
- EMC implementation - Standards
- EMC implementation - Electrostatic discharge protection
- EMC - Coupling mechanisms and counter-measures
- Wiring recommendations
- Measurement
