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Transcript
PowerPoint® Presentation Photovoltaic Systems Solar Electrical Integration National Electrical Code • Voltage and Current Requirements • Conductors and Wiring Methods • Overcurrent Protection • Disconnects • Grounding • Battery Systems Arizona Solar Power Society www.meetup.com/arizona-solar-power-society/ Chapter 11 — Electrical Integration Many articles in the NEC® are applicable to the electrical integration of a PV system, particularly Article 690. Chapter 11 — Electrical Integration The NEC® defines the various circuits and components in PV systems and specifies their requirements. Chapter 11 — Electrical Integration Array open-circuit voltage is corrected for low temperatures to yield the maximum possible PV circuit voltage. Chapter 11 — Electrical Integration Conductor sizes typically used in PV systems range from 18 AWG to 4/0 AWG. Conductors may be solid or stranded. Larger conductors have lower resistance for a given length. Chapter 11 — Electrical Integration Ampacity is the currentcarrying capacity of a conductor, which depends on the conductor’s type, size, and application. Chapter 11 — Electrical Integration Conductor ampacity must be derated for high temperatures. Chapter 11 — Electrical Integration For conduits installed on rooftops, an extra temperature adder is needed to account for the extreme ambient temperatures of the environment. The adjusted ambient temperature is then used to determine the temperaturebased ampacity correction factor. Chapter 11 — Electrical Integration Conductor ampacity must be derated for more than three current-carrying conductors together in a conduit or cable. Chapter 11 — Electrical Integration Size, insulation type, resistances, and other information are printed on the outer jacket of conductors. Chapter 11 — Electrical Integration Conductors in different parts of a PV system have different application requirements. Chapter 11 — Electrical Integration Source-circuit conductors are permitted to be exposed if the conductor insulation has the required environmental resistances. Chapter 11 — Electrical Integration Modules are typically connected together in PV source circuits with external, exposed connectors. Chapter 11 — Electrical Integration When tightened properly, screw terminals produce secure and lowresistance connections. Chapter 11 — Electrical Integration Lugs are crimped conductor terminations in ring, fork, spade, or pin shapes. Chapter 11 — Electrical Integration Splicing devices, such as screw terminal blocks, are used in PV systems to connect or extend conductors, parallel array source circuits, or tap service-entrance conductors for supplyside interconnections. Chapter 11 — Electrical Integration Several NEMA plug-andreceptacle configurations are acceptable for use with DC branch circuits. Chapter 11 — Electrical Integration Module junction boxes contain and protect the module terminal connections and diodes in the source circuit. Some are fieldaccessible. Chapter 11 — Electrical Integration Multiple PV source circuits are combined into the PV output circuit within the combiner box. Chapter 11 — Electrical Integration Blocking diodes are installed in the source circuit and bypass diodes are installed within a module or its junction box. These diodes prevent power loss due to reverse current or high-resistance conditions. Chapter 11 — Electrical Integration Bypass diodes may be field-installed in the module junction box. Chapter 11 — Electrical Integration A number of different types of conduit may be used in PV systems if they have the necessary resistances, such as moisture and high temperature resistance for source circuits. Chapter 11 — Electrical Integration Current-limiting overcurrent protection devices open a short circuit before current reaches its highest value. Chapter 11 — Electrical Integration Overcurrent protection devices include fuses and circuit breakers of various types and ratings. Chapter 11 — Electrical Integration Array source circuits are fused individually within the source-circuit combiner box. Chapter 11 — Electrical Integration Overcurrent protection for the inverter output circuit depends on the system or utility interconnection type. Overcurrent protection and disconnecting means for this circuit may also be combined by using circuit breakers or fused disconnects. Chapter 11 — Electrical Integration Connecting a 120 V inverter to a 120/240 V system with multiwire branch circuits causes dangerous overloading in the grounded (neutral) conductor and must be avoided. Chapter 11 — Electrical Integration The array disconnect opens all current-carrying conductors in the PV output circuit. Chapter 11 — Electrical Integration The AC disconnect of an interactive PV system may be located close to the main utility service disconnect, which can satisfy utility requirements for an external, visible-break, and lockable PV system disconnect. Chapter 11 — Electrical Integration Switches or circuit breakers are required to isolate and disconnect all major components in a PV system from all ungrounded conductors of all power sources. Chapter 11 — Electrical Integration The DC grounding system and the AC grounding system must be connected together with a bonding conductor. The array may also require a separate grounding electrode system. Chapter 11 — Electrical Integration Some inverters include fuses as array ground-fault protection in their DC input circuits. Chapter 11 — Electrical Integration Circuit breakers can be used for array groundfault protection when the inverter does not already provide this protection. Chapter 11 — Electrical Integration A ground-fault circuit interrupter (GFCI) senses differences between the current in the grounded and ungrounded conductors, indicating a ground fault, and opens the circuit in response. Chapter 11 — Electrical Integration Modules should be connected to each other and the mounting structure with grounding conductors to ensure a continuous grounding connection. Chapter 11 — Electrical Integration Equipment grounding conductors are sized based on the rating of the overcurrent protection device in the circuit. Chapter 11 — Electrical Integration Lightning protection is especially important in the southeastern states, which have the highest lightning-strike density in the United States. Chapter 11 — Electrical Integration A lightning protection system includes a network of air terminals, a grounding electrode (down) conductor, and a set of grounding electrodes. Chapter 11 — Electrical Integration Surge arrestors may be incorporated into equipment or can be installed on circuits as separate devices. Chapter 11 — Electrical Integration Connectors may be used for disconnecting highvoltage battery banks for servicing.
