Electrical Service Entrance

Revision 1 · SynC Standards Team — Specifier, SynC (SynC Platform Team / Platform Standards) ✓ Official · Jun 13, 2026 +650 −0

Initial publication

Showing changes from Initial revision to Rev 1 in Electrical Service Entrance.

+---

+title: Electrical Service Entrance

+category: Electrical / Power Distribution Equipment

+toc_depth: 3

+description: >

+ When to use: design, specification, and installation of low-voltage (600 V class) electrical

+ service entrances for commercial, industrial, and multi-family residential buildings — from the

+ utility point of delivery through the service disconnecting means. Covers overhead service drops

+ and underground laterals, service-entrance conductors, weatherheads and risers, meter sockets and

+ metering enclosures, combination service-entrance devices (CSEDs / meter-mains), service

+ disconnects, ground-fault protection of equipment (GFPE), emergency disconnects, service

+ enclosures, and the utility-to-owner interface, for new construction and service upgrades at

+ 120/240 V 1Φ, 120/208 V 3Φ, and 277/480 V 3Φ.

+ Not intended for: distribution switchboards and switchgear downstream of the service disconnect

+ (use [[sync/low-voltage-switchboards]]); service-point and pad-mounted transformers (use

+ [[sync/transformers]]); grounding electrode conductors, ground rods, and bonding jumpers (use

+ [[sync/grounding-and-bonding]]); revenue metering instruments and power monitoring beyond the

+ basic utility meter socket (use [[sync/electrical-power-monitoring]]); motor starters and branch

+ overcurrent devices (use [[sync/combination-motor-starters]]); generator paralleling and automatic

+ transfer switches at the service entrance; and medium-voltage (>600 V) primary services and

+ primary metering.

+---

+# Scope {toc}

+## This standard governs the electrical service entrance: the equipment and conductors that carry electrical power from the utility point of delivery to and through the service disconnecting means for a building or structure. {note}

+## The service entrance is the legal and physical boundary between utility-owned infrastructure and customer-owned premises wiring. {note}

+## Everything downstream of the service disconnect — the building's feeders, branch circuits, and distribution equipment — is governed by other standards. Everything upstream of the point of delivery is the serving utility's responsibility under IEEE C2 (NESC), not the National Electrical Code, and is not in the contractor's scope except for the coordination, conduit, and mounting provisions this standard requires. {note}

+## Service equipment furnished and installed under this standard shall be listed and labeled for use as service equipment.

+## The work shall comply with NFPA 70 (NEC) Article 230, the serving utility's electric service requirements manual, and the authority having jurisdiction.

+## Where the serving utility's published requirements are more restrictive than this standard, the utility's requirements shall govern for all equipment on the utility side of the point of delivery, including metering provisions. {note}

+## Utilities maintain approved-equipment lists, meter-socket jaw configurations, current-transformer ratios, and mounting-height rules that override a generic specification. Confirming these before rough-in is a recurring source of rejected work when skipped. {note}

+## This standard does not cover automatic transfer switches or generator connections made at the service entrance. {note}

+## Automatic transfer switch and generator connection arrangements at the service entrance shall be specified separately and coordinated with this standard.

+# Referenced Standards {toc}

+## Equipment, materials, and installation shall comply with the latest adopted edition of each of the following unless a specific edition is cited.

+## Where referenced standards conflict, the more stringent requirement shall govern unless the Engineer of Record directs otherwise in writing.

+| Standard | Title |

+|----------|-------|

+| NFPA 70 (NEC) 2023, Article 230 | Services — Service Conductors and Equipment |

+| NEC 2023, 230.42 | Minimum Size and Ampacity of Service-Entrance Conductors |

+| NEC 2023, 230.70 | Service Disconnecting Means — General |

+| NEC 2023, 230.71 | Maximum Number of Disconnects |

+| NEC 2023, 230.85 | Emergency Disconnects (one- and two-family dwellings) |

+| NEC 2023, 230.95 | Ground-Fault Protection of Equipment |

+| NEC 2023, Table 300.5 | Minimum Cover Requirements for Underground Installations |

+| NEC 2023, Table 310.12 | Single-Phase Dwelling Services and Feeders |

+| UL 869A | Reference Standard for Service Equipment |

+| UL 414 | Meter Sockets |

+| UL 67 | Panelboards |

+| UL 489 | Molded-Case Circuit Breakers, Molded-Case Switches, and Circuit Breaker Enclosures |

+| UL 98 | Enclosed and Dead-Front Switches |

+| ANSI/NEMA PB 2 | Deadfront Distribution Switchboards |

+| IEEE C2 (NESC) 2023 | National Electrical Safety Code |

+| NFPA 70E 2024 | Standard for Electrical Safety in the Workplace |

+# Utility Coordination and Point of Delivery {toc}

+## The point of delivery (POD) is the location where the serving utility's conductors terminate and ownership transfers to the customer; it shall be identified on the contract drawings. {note}

+## For an overhead service, the POD is typically the service-drop attachment point at the weatherhead. For an underground service, it is typically the secondary terminals of the utility transformer or a designated junction. The POD divides NESC-governed (utility) work from NEC-governed (customer) work; misplacing it produces scope disputes and double-counted or orphaned equipment. {note}

+## The Contractor shall obtain the serving utility's current electric service requirements manual before specifying or ordering any service equipment.

+## The Contractor shall submit the utility service application and obtain utility approval of the service-entrance arrangement before commencing rough-in.

+## The available fault current (AFC) at the service point shall be requested in writing from the serving utility during design and shall not be assumed. {note}

+## The AFC sets the minimum short-circuit current rating (SCCR / AIC) for all service equipment. Specifying equipment with an AIC below the actual utility fault current is a safety defect, not merely a code violation; it cannot be discovered by inspection of a nameplate alone and must be designed against from a utility-furnished value. {note}

+## The metering arrangement — self-contained (socket) metering or current-transformer (CT) metering — shall be coordinated with the serving utility, and CT ratios shall match the utility's revenue meter and data-acquisition requirements.

+## Utility easement and right-of-way constraints for underground lateral routing and transformer pad placement shall be coordinated with the civil and site work before the service location is fixed. {note}

+```datasheet

+label: Service entry type

+type: radio

+options:

+ - Overhead service drop (weatherhead and riser)

+ - Underground service lateral

+default: Underground service lateral

+```

+```datasheet

+label: Point of delivery location

+type: text

+drawing_ref: true

+default: deferred

+```

+# Service Characteristics {toc}

+## The service voltage, phase configuration, and number of wires shall match the serving utility's available distribution and the building's calculated load. {note}

+## Three configurations dominate low-voltage services: 120/240 V single-phase three-wire (most residential and light commercial), 120/208 V three-phase four-wire (commercial with mixed lighting and three-phase motor load), and 277/480 V three-phase four-wire (larger commercial and industrial, where 277 V lighting and 480 V motors reduce conductor size and losses). The main disconnect voltage rating shall match the system voltage per NEC 230.82. {note}

+## A single service shall supply the building unless the conditions of NEC 230.2 for additional services are met and documented.

+```datasheet

+label: Service voltage and phase

+type: radio

+options:

+ - 120/240 V 1Φ 3-wire

+ - 120/208 V 3Φ 4-wire

+ - 277/480 V 3Φ 4-wire

+default: 120/208 V 3Φ 4-wire

+```

+```datasheet

+label: Service ampacity (main disconnect rating)

+type: select

+unit: A

+options:

+ - "100"

+ - "200"

+ - "400"

+ - "600"

+ - "800"

+ - "1200"

+ - "1600"

+ - "2000"

+ - "3000"

+default: "200"

+```

+```datasheet

+label: Available fault current (utility-declared, symmetrical)

+type: range

+unit: kA

+min: 10

+max: 65

+step: 1

+default: 42

+```

+## The service-equipment short-circuit current rating (SCCR / AIC) shall equal or exceed the utility-declared available fault current at the service point.

+```datasheet

+label: Minimum equipment short-circuit current rating (AIC)

+type: select

+unit: kAIC

+options:

+ - "22"

+ - "42"

+ - "65"

+ - "100"

+default: "65"

+```

+# Submittals {toc}

+## Action Submittals {toc}

+### The Contractor shall submit the following action submittals for review before fabrication or ordering:

+- Product data for service equipment, meter sockets, CSEDs, and disconnecting means, with listing marks and SCCR ratings.

+- Shop drawings showing the complete service-entrance arrangement, conductor routing, conduit sizes, and equipment dimensions.

+- Service-entrance conductor sizing calculations per NEC 230.42, including adjustment and correction factors.

+- Available-fault-current documentation from the utility and the corresponding equipment SCCR.

+- Evidence of compliance with the serving utility's approved-equipment list and metering requirements.

+```datasheet

+label: Action submittals required

+type: checkbox

+options:

+ - Product data (service equipment, sockets, disconnects)

+ - Shop drawings (service-entrance arrangement)

+ - Conductor sizing calculations

+ - Available-fault-current documentation

+ - Utility approved-equipment compliance

+default:

+ - Product data (service equipment, sockets, disconnects)

+ - Shop drawings (service-entrance arrangement)

+ - Conductor sizing calculations

+ - Available-fault-current documentation

+ - Utility approved-equipment compliance

+```

+## Informational Submittals {toc}

+### The Contractor shall submit the following informational submittals:

+- The serving utility's service application and written service approval.

+- Manufacturer's installation instructions for service equipment and meter enclosures.

+- Field test reports for ground-fault protection of equipment, where GFPE is provided.

+```datasheet

+label: Informational submittals required

+type: checkbox

+options:

+ - Utility service application and approval

+ - Manufacturer installation instructions

+ - GFPE field performance test report

+default:

+ - Utility service application and approval

+ - Manufacturer installation instructions

+```

+## Closeout Submittals {toc}

+### The Contractor shall submit the following closeout submittals:

+- Record drawings showing the as-installed service-entrance arrangement and conductor routing.

+- Final arc-flash and equipment labeling documentation per NFPA 70E.

+- Warranty documentation for the service equipment.

+```datasheet

+label: Closeout submittals required

+type: checkbox

+options:

+ - As-installed record drawings

+ - Arc-flash and equipment labels

+ - Warranty documentation

+default:

+ - As-installed record drawings

+ - Arc-flash and equipment labels

+ - Warranty documentation

+```

+# Quality Assurance {toc}

+## Service equipment shall be listed and labeled to UL 869A or the applicable individual product standard (UL 414 for meter sockets, UL 67 for panelboards in CSEDs, UL 489 for molded-case breakers, UL 98 for fusible switches).

+## The installer shall be a licensed electrical contractor experienced in service-entrance work and acceptable to the serving utility for metering installations.

+## The Engineer of Record shall verify that the equipment SCCR shown on submittals equals or exceeds the utility-declared available fault current before approving the equipment for fabrication.

+## All service equipment shall bear the labeling required by NEC 110.24 for available fault current and the date of calculation. {note}

+# Environmental and Service Conditions {toc}

+## The service-equipment enclosure NEMA rating shall suit the installed environment. {note}

+## Outdoor and exterior-wall installations require a minimum NEMA 3R rainproof enclosure. NEMA 1 general-purpose enclosures are acceptable only indoors in dry locations. Wet, washdown, coastal, or chemically corrosive environments require NEMA 4 or NEMA 4X (stainless or non-metallic). Specifying NEMA 1 for an exterior meter socket is a common and avoidable inspection rejection. {note}

+## Equipment shall be rated for the ambient temperature range and altitude of the installation, and conductor ampacity shall be corrected for ambient temperature per NEC 310.

+```datasheet

+label: Enclosure environmental rating

+type: radio

+options:

+ - NEMA 1 (indoor, dry)

+ - NEMA 3R (outdoor, rainproof)

+ - NEMA 4 (watertight)

+ - NEMA 4X (watertight, corrosion-resistant)

+default: NEMA 3R (outdoor, rainproof)

+```

+# Service-Entrance Conductors {toc}

+## Service-entrance conductors shall be sized to carry the calculated load per NEC 230.42 and shall be not smaller than the minimum required for the service rating. {note}

+## Conductor ampacity is determined from the Article 220 load calculation for commercial work, or from NEC Table 310.12 for single-phase dwelling services (which permits an 83% demand factor). The 2023 NEC restructured 230.42 into subsections (A)(1) and (A)(2), clarifying how continuous/noncontinuous load factors and the ampacity adjustment and correction factors are applied — an update that can increase the required conductor size relative to prior editions. {note}

+## Service-entrance conductors shall not be smaller than required for a 100 A service for a one-family dwelling per NEC 230.79(C).

+## Where aluminum conductors are used, the service-equipment terminations shall be listed for aluminum (AL/CU), and the connections shall be made with antioxidant compound and torqued to the manufacturer's published values. {note}

+## Aluminum is routinely specified for service conductors on cost and weight grounds, but a copper-only termination on aluminum conductors, or an untreated/under-torqued aluminum connection, produces a high-resistance joint that overheats. Confirming the termination rating is a specification responsibility, not a field assumption. {note}

+## Conductors installed in conduit shall comply with the conduit-fill limits of NEC Chapter 9, Table 1.

+```datasheet

+label: Service-entrance conductor material

+type: radio

+options:

+ - Copper

+ - Aluminum

+default: Aluminum

+```

+```datasheet

+label: Conductor insulation type

+type: select

+options:

+ - XHHW-2

+ - RHW-2

+ - THWN-2

+ - USE-2 (underground)

+ - SER cable

+default: XHHW-2

+```

+```datasheet

+label: Service-entrance conductor size

+type: text

+drawing_ref: true

+default: deferred

+```

+# Overhead Service {toc}

+## Where an overhead service is provided, a weatherhead shall terminate the service-entrance raceway above the service-drop attachment, with drip loops formed in the conductors. {note}

+## The weatherhead and conduit riser carry the service-entrance conductors from the meter up to the utility's service-drop splice. The drip loop and the weatherhead's downward-facing, gasketed openings keep water from tracking into the raceway and the meter enclosure. {note}

+## The service-drop point of attachment shall be not less than 3.0 m (10 ft) above finished grade at the electrical service-entrance conductors per NEC 230.26.

+## Overhead service-drop conductors shall maintain the minimum vertical clearances above grade, driveways, and roadways established by the NEC and NESC. {note}

+## The governing minimums are 3.0 m (10 ft) above grade at the service point, 3.7 m (12 ft) above residential driveways, and 5.5 m (18 ft) above public streets and roads. These are utility-side (NESC) clearances that constrain where the attachment and riser can be placed; they must be confirmed against site conditions before the riser location is fixed. {note}

+```datasheet

+label: Service-drop attachment height above grade

+type: range

+unit: ft

+min: 10

+max: 30

+step: 1

+default: 12

+```

+```datasheet

+label: Riser conduit material (overhead)

+type: select

+options:

+ - Rigid metal conduit (RMC)

+ - Intermediate metal conduit (IMC)

+ - Rigid PVC Schedule 80

+default: Rigid metal conduit (RMC)

+```

+# Underground Service {toc}

+## Where an underground service lateral is provided, the service-entrance conductors shall be installed in raceway or as listed underground cable at the minimum cover required by NEC Table 300.5. {note}

+## The minimum cover depends on the wiring method: 600 mm (24 in.) for direct-buried USE-2 cable, rigid metal conduit, IMC, and rigid nonmetallic conduit at residential and light-commercial services. Schedule 40 PVC at 600 mm (24 in.) depth is the most common arrangement. HDPE duct and concrete-encased ducts have their own listed cover values. {note}

+## Underground conductors shall be type USE-2 or installed in raceway with conductors listed for wet locations, since the interior of an underground raceway is a wet location.

+## Where service raceways enter a building from underground, the raceway shall be sealed against the entry of moisture, gases, and vermin per NEC 230.8. {note}

+## A duct-seal or listed sealing fitting at the building entry is required by code and is frequently omitted; without it, soil gases and condensation track into the service equipment and corrode terminations. {note}

+```datasheet

+label: Underground raceway material

+type: select

+options:

+ - Rigid PVC Schedule 40

+ - Rigid PVC Schedule 80

+ - HDPE duct

+ - Rigid metal conduit (RMC)

+default: Rigid PVC Schedule 40

+```

+```datasheet

+label: Minimum cover (underground service)

+type: range

+unit: in

+min: 18

+max: 36

+step: 1

+default: 24

+```

+```datasheet

+label: Underground lateral routing

+type: text

+drawing_ref: true

+default: deferred

+```

+# Metering {toc}

+## A meter socket or metering enclosure shall be provided in conformance with the serving utility's requirements, listed to UL 414, and positioned for the utility's access. {note}

+## The meter socket type — ringless or ring-type, four-jaw or five-jaw, single-position or multi-position — is dictated by the serving utility, not the engineer. Self-contained (socket) metering is used up to 200 A class; larger services and many commercial services use CT metering, where current transformers feed an instrument-grade meter socket. Specifying a socket configuration the utility will not accept forces a field change at the worst possible time. {note}

+## Self-contained meter sockets shall be provided with a bypass provision where required by the serving utility to permit meter replacement without interrupting service.

+## For services above the self-contained metering limit, a current-transformer metering compartment shall be provided with CT ratios matched to the utility's revenue meter. {note}

+## Multi-tenant buildings requiring individual tenant metering shall be provided with gang (multi-position) meter stacks, with each position rated for the tenant service ampacity. {note}

+## Two- through six-position meter stacks serve multifamily and multi-tenant buildings, each position typically 100 A to 200 A. Each tenant position is a separate service or a separate disconnect grouping and must be labeled to identify the load served. {note}

+## The meter shall be mounted so the center of the meter is at the height above finished grade required by the serving utility, typically between 1.1 m (3.5 ft) and 1.8 m (6 ft).

+```datasheet

+label: Metering type

+type: radio

+options:

+ - Self-contained socket meter (200 A class)

+ - CT metering (current-transformer compartment)

+ - Multi-position gang meter stack

+default: Self-contained socket meter (200 A class)

+```

+```datasheet

+label: Meter socket configuration

+type: radio

+options:

+ - Ringless

+ - Ring-type

+default: Ringless

+```

+```datasheet

+label: Number of metering positions (gang stacks)

+type: range

+unit: position

+min: 1

+max: 6

+step: 1

+default: 1

+```

+```datasheet

+label: Meter center height above finished grade

+type: range

+unit: ft

+min: 3.5

+max: 6

+step: 0.5

+default: 5

+```

+# Service Disconnecting Means {toc}

+## A means to disconnect all ungrounded service conductors from the building shall be provided per NEC 230.70. {note}

+## The service disconnect is the building's main "off" switch and the dividing point at which utility power can be removed from the premises wiring. It may be a molded-case main circuit breaker (UL 489), a fusible switch (UL 98), or the main section of a service-entrance switchboard (ANSI/NEMA PB 2). {note}

+## The service disconnect shall be installed at the nearest practicable point to the entrance of the service conductors, either outside the building or inside nearest the point of entrance per NEC 230.70(A)(1). {note}

+## Excess service-conductor length inside the building between the meter and the main disconnect is unprotected by the service overcurrent device and is a frequent inspection rejection. An exterior disconnect is preferred where practicable because it lets first responders de-energize the building without entering it. {note}

+## The service disconnect shall be legibly marked to identify it as the service disconnecting means and shall indicate the load served.

+## A single service disconnect should be provided for each service.

+## NEC 230.71 permits up to six service disconnects in a grouping for certain individual-occupancy arrangements, but a single main disconnect is the clearer and more defensible design for most commercial buildings and avoids ambiguity about which switch removes all service power. Multiple-disconnect groupings should be reserved for genuine multi-occupancy conditions and shall meet all conditions of 230.71. {note}

+## The disconnecting means shall be listed and rated for use as service equipment, with a short-circuit current rating not less than the available fault current.

+```datasheet

+label: Service disconnect device type

+type: radio

+options:

+ - Main circuit breaker (molded-case)

+ - Fusible switch

+ - Switchboard main section

+default: Main circuit breaker (molded-case)

+```

+```datasheet

+label: Number of service disconnects

+type: radio

+options:

+ - Single main disconnect

+ - Grouped disconnects (up to six, NEC 230.71)

+default: Single main disconnect

+```

+# Combination Service-Entrance Devices {toc}

+## Where a combination service-entrance device (CSED / meter-main) is provided, it shall integrate the meter socket and the service disconnect in a single listed enclosure rated for the service entry method. {note}

+## A CSED combines the meter socket and the main breaker (and often a small panelboard) in one outdoor- or underground-rated enclosure. It is the standard arrangement for residential and light-commercial services up to about 400 A and reduces the conductor run between meter and disconnect to a minimum. {note}

+## A CSED shall not be specified for services above its listed maximum rating; services exceeding the CSED range shall use a separate meter socket and switchboard or switchgear arrangement. {note}

+## Most CSEDs are listed only to 400 A. Specifying a single meter-main for a larger service is a recurring design error that surfaces as a procurement dead-end; above the CSED range the meter and the disconnect become separate assemblies. {note}

+```datasheet

+label: Service-entrance assembly type

+type: radio

+options:

+ - Separate meter socket and main disconnect

+ - Combination service-entrance device (CSED / meter-main)

+ - Service-entrance switchboard section

+default: Separate meter socket and main disconnect

+```

+# Ground-Fault Protection of Equipment {toc}

+## Ground-fault protection of equipment (GFPE) shall be provided on each service disconnect rated 1000 A or more on a solidly grounded wye service of more than 150 V to ground but not exceeding 600 V phase-to-phase, per NEC 230.95. {note}

+## In practice this means GFPE is required on 480Y/277 V services with a service disconnect of 1000 A or larger. GFPE detects a phase-to-ground fault that is too small to trip the overcurrent device quickly but large enough to do severe arcing damage, and it opens the disconnect on that ground current alone. The most common coordination failure is when the main switchboard is specified by a different section and GFPE is omitted because neither section claimed it. {note}

+## The GFPE maximum setting shall not exceed 1200 A, and the maximum time delay shall not exceed one second for ground-fault currents of 3000 A or greater, per NEC 230.95(A).

+## A field performance test of the ground-fault protection system shall be performed when the equipment is first installed, per NEC 230.95(C), and the written results shall be submitted before energization. {note}

+## The 230.95(C) test is a code requirement, not optional commissioning. It verifies, by primary or secondary current injection with calibrated equipment, that the GFPE actually trips at the intended pickup and time delay. Treating it as discretionary commissioning is a code violation. {note}

+```datasheet

+label: GFPE provided

+type: radio

+options:

+ - Required (480Y/277 V service, disconnect ≥ 1000 A)

+ - Not required

+default: Not required

+```

+```datasheet

+label: GFPE pickup setting

+type: range

+unit: A

+min: 100

+max: 1200

+step: 100

+default: 600

+```

+```datasheet

+label: GFPE maximum time delay at ≥ 3000 A

+type: range

+unit: s

+min: 0.1

+max: 1.0

+step: 0.1

+default: 0.2

+```

+# Emergency Disconnect {toc}

+## For one- and two-family dwelling units, an emergency disconnect shall be installed in a readily accessible outdoor location per NEC 230.85. {note}

+## This is a 2023 NEC addition. It requires an outdoor disconnecting means even when the main service panel is indoors, so that first responders can de-energize a dwelling from outside. The emergency disconnect shall be marked per 230.85 to identify its function (service disconnect, meter disconnect, or emergency disconnect not service equipment). {note}

+## The emergency disconnect shall be legibly marked with the wording required by NEC 230.85 to identify its type and function.

+```datasheet

+label: Emergency disconnect (one- and two-family dwellings)

+type: radio

+options:

+ - Provided (outdoor, readily accessible)

+ - Not applicable (non-dwelling occupancy)

+default: Not applicable (non-dwelling occupancy)

+```

+# Enclosures and Mounting {toc}

+## Service-equipment enclosures shall be securely mounted to a structural surface or a freestanding rack rated for the equipment weight and the seismic conditions of the site.

+## Outdoor-mounted enclosures shall be NEMA 3R minimum and shall be installed with the required working clearances in front of the equipment maintained per NEC 110.26. {note}

+## Working-clearance violations — equipment crowded into an alcove, against a fence, or behind a door swing — are among the most common service-entrance rejections and are dangerous to maintain. The clearance depth, width, and headroom of NEC 110.26 must be reserved on the drawings, not discovered in the field. {note}

+## Service-entrance raceways and enclosures shall be bonded as required for service equipment; grounding electrode and bonding details are governed by [[sync/grounding-and-bonding]]. {note}

+```datasheet

+label: Enclosure mounting

+type: radio

+options:

+ - Surface-mounted on building wall

+ - Freestanding on rack or pad

+ - Recessed (flush) in wall

+default: Surface-mounted on building wall

+```

+# Identification and Arc-Flash Labeling {toc}

+## Service equipment shall be field-marked with an arc-flash warning label and the available incident energy or required PPE category per NFPA 70E. {note}

+## The arc-flash label tells anyone opening the equipment what hazard they face and what PPE is required. At the service entrance the available fault current is at its highest, so the incident energy can be severe; the label is both a safety requirement and a maintenance prerequisite. {note}

+## Each disconnect shall be permanently labeled to identify the load it serves and, where multiple disconnects are grouped, to identify it as one of a group of service disconnects.

+# Testing {toc}

+## Before energization, the Contractor shall verify torque on all service-conductor terminations to the manufacturer's published values and shall document the results.

+## Insulation resistance of the service-entrance conductors shall be tested before energization.

+## The service-entrance conductors shall be free of grounds and shorts.

+## Where GFPE is provided, the field performance test required by NEC 230.95(C) shall be completed and documented before the service is energized.

+## Phase rotation shall be verified on three-phase services before connecting downstream equipment.

+```datasheet

+label: Pre-energization tests required

+type: checkbox

+options:

+ - Termination torque verification

+ - Insulation resistance test

+ - GFPE field performance test (where provided)

+ - Phase rotation verification (3Φ)

+default:

+ - Termination torque verification

+ - Insulation resistance test

+ - Phase rotation verification (3Φ)

+```

+# Installation {toc}

+## The service entrance shall be installed in accordance with the approved shop drawings, the manufacturer's installation instructions, NEC Article 230, and the serving utility's requirements.

+## Service-entrance conductors shall be continuous without splice from the point of delivery to the service disconnect except where splices are specifically permitted by NEC 230.46. {note}

+## The length of service-entrance conductors inside the building ahead of the service disconnect shall be kept to the minimum practicable. {note}

+## Conductors ahead of the service disconnect are not protected by the service overcurrent device, so every additional foot inside the building is unprotected and increases the fire exposure of an unfused fault. The code intent of "nearest the point of entrance" is to make this length as short as the construction allows. {note}

+## Underground raceways entering the building shall be sealed per NEC 230.8 after conductors are installed.

+## Equipment shall be installed plumb, level, and with all manufacturer-required working clearances maintained.

+## Field-installed service-equipment labels and arc-flash labels shall be applied before the equipment is placed in service.

+# Delivery, Storage, and Handling {toc}

+## Service equipment shall be delivered in the manufacturer's original packaging with listing labels intact and shall be inspected for transit damage on receipt.

+## Equipment shall be stored indoors in a clean, dry, conditioned space until installation; outdoor-rated equipment stored outdoors shall be protected from standing water and covered to exclude construction dust and debris.

+## Equipment shall be handled and lifted at the manufacturer's designated lifting points and shall not be lifted by bus, breakers, or meter jaws.

+# Warranty {toc}

+## The manufacturer shall warrant the service equipment against defects in materials and workmanship for not less than one year from the date of energization or substantial completion, whichever is later.

+```datasheet

+label: Warranty period

+type: select

+unit: years

+options:

+ - "1"

+ - "2"

+ - "5"

+default: "1"

+```

+# Spare Parts {toc}

+## The Contractor shall furnish spare fuses of each type and rating installed in fusible service equipment, in the quantity required by the project specifications.

+## For services with field-replaceable trip units or control power components, the Contractor shall furnish the manufacturer's recommended spare-parts list for owner stock. {note}

+```datasheet

+label: Spare parts to be furnished

+type: checkbox

+options:

+ - Spare fuses (each type and rating, fusible switches)

+ - Spare control-power fuses (GFPE/relays)

+ - Manufacturer recommended spares list

+default:

+ - Spare fuses (each type and rating, fusible switches)

+```

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