1 Scope
NOTE This specification covers the performance and reporting of a short-circuit study for the project's electrical power distribution system. (1.1)
1.2 The study shall calculate the available short-circuit current at every point in the distribution system at which an interrupting device, a passive current-carrying component, or an equipment short-circuit current rating must be verified.
1.3 Calculated values shall be used to confirm that every installed and proposed device has an interrupting rating equal to or greater than the available fault current at its line terminals.
1.4 Calculated values shall be used to confirm that every bus, cable, and bracing system is rated to withstand the available fault current for the duration required by the upstream protective devices.
NOTE The short-circuit study is one of three power studies that are commonly performed together for the same distribution system. (1.5)
NOTE The short-circuit study establishes the magnitudes of fault current; the protective coordination study (see
Protective Coordination Study) establishes how those fault currents are cleared by upstream and downstream devices; and the arc flash study (see
Arc Flash Study) translates the cleared fault current and clearing time into incident energy for personnel protection.
(1.6) 1.7 The three studies share input data and shall be performed by the same engineering organization where practical to avoid inconsistent system modeling between studies.
NOTE A short-circuit study is a deliverable of the design and construction process; it is not a substitute for the contractor's responsibility to obtain and apply the available fault current value from the serving utility, nor for the electrical engineer of record's responsibility to specify equipment with adequate interrupting ratings on the contract documents. (1.8)
2 Referenced Standards
2.1 The study, its inputs, and its deliverables shall comply with the latest adopted edition of the following standards and codes.
2.2 Where the contract documents, the adopted building code, or a referenced standard conflict, the more stringent requirement shall govern unless the Engineer of Record directs otherwise in writing.
2.3 Referenced Standards List
| Standard |
Title |
| NFPA 70 |
National Electrical Code (Articles 110.9, 110.10, 110.16, 110.24, 240.86) |
| NFPA 70E |
Standard for Electrical Safety in the Workplace |
| OSHA 29 CFR 1910.303 |
General Requirements for Electric Utilization Equipment |
| IEEE 141 |
Recommended Practice for Electric Power Distribution for Industrial Plants (Red Book) |
| IEEE 241 |
Recommended Practice for Electric Power Systems in Commercial Buildings (Gray Book) |
| IEEE 399 |
Recommended Practice for Industrial and Commercial Power Systems Analysis (Brown Book) |
| IEEE 551 |
Recommended Practice for Calculating AC Short-Circuit Currents in Industrial and Commercial Power Systems (Violet Book) |
| IEEE 3002.3 |
Recommended Practice for Conducting Short-Circuit Studies and Analysis of Industrial and Commercial Power Systems |
| ANSI C37.010 |
Application Guide for AC High-Voltage Circuit Breakers Rated on a Symmetrical Current Basis |
| ANSI C37.13 |
Low-Voltage AC Power Circuit Breakers Used in Enclosures |
| ANSI C37.06 |
AC High-Voltage Circuit Breakers Rated on a Symmetrical Current Basis — Preferred Ratings |
| UL 489 |
Molded-Case Circuit Breakers, Molded-Case Switches, and Circuit-Breaker Enclosures |
| UL 248 |
Low-Voltage Fuses |
| IEC 60909 |
Short-Circuit Currents in Three-Phase AC Systems (where IEC methodology is specified) |
| ANSI/NETA ATS |
Standard for Acceptance Testing Specifications for Electrical Power Equipment and Systems |
NOTE The relevant NEC sections shall be understood as the legal driver of the study's purpose: NEC 110.9 requires that equipment intended to interrupt fault current have an interrupting rating sufficient for the available fault current at its line terminals; NEC 110.10 requires that the entire circuit — overcurrent device, conductors, and equipment — be coordinated so that components are not damaged by a fault; and OSHA 29 CFR 1910.303(b)(4) and (b)(5) impose substantively the same requirements as federal workplace safety rules. (2.4)
NOTE The short-circuit study is the calculation that proves compliance with NEC 110.9, NEC 110.10, and OSHA 29 CFR 1910.303. (2.5)
● Independent registered Professional Engineer (PE), licensed in the project state
○ Equipment manufacturer's engineering services (PE-stamped)
○ Testing agency engineering services (PE-stamped)
○ Contractor's engineering subcontractor (PE-stamped)
● Required — review by the Engineer of Record before acceptance
○ Not required — engineer of record relies on performer's PE seal
3.1 The short-circuit study shall be performed under the responsible charge of a Professional Engineer licensed in the state where the project is located.
3.2 The final study report, all single-line diagrams, and all calculation summaries shall be sealed and signed by that engineer.
3.3 The performer shall demonstrate a minimum of five years of documented experience performing short-circuit studies on power systems of comparable size and complexity.
NOTE An independent engineering firm is preferred over a manufacturer-affiliated performer where the study results may influence equipment procurement decisions, because a manufacturer-performed study has an inherent conflict of interest in concluding that its own equipment is adequately rated. (3.4)
3.5 Where the manufacturer performs the study under a furnished-equipment scope, the study shall be subject to independent review.
3.6 The Contractor shall not self-perform the short-circuit study without engaging a qualified engineer.
NOTE A study performed by a non-engineer using the output of a software tool without engineering judgment is not acceptable, regardless of the tool used, because the inputs, assumptions, and interpretation of results require professional engineering review. (3.7)
4 Submittals
4.1 Action Submittals
4.1.1 The Contractor shall submit the following for the Engineer's review before any equipment subject to study findings is procured or fabricated:
- Study performer's qualifications, including PE license verification and project experience
- Description of the calculation methodology, software, and standard (ANSI/IEEE or IEC) to be used
- Proposed list of system data sources, including utility short-circuit data request status, equipment nameplate data sources, and any assumptions for missing data
- Preliminary single-line diagram with all buses, branches, and devices labeled with the identifiers that will be used in the study report
- Study schedule showing key milestones and final delivery date relative to equipment procurement deadlines
☑ Performer qualifications and PE license
☐ Calculation methodology description
☐ Data source list and assumption log
☐ Preliminary single-line diagram with bus identifiers
☐ Study schedule
4.1.2 Equipment procurement shall not proceed for any item whose interrupting rating, withstand rating, or short-circuit current rating depends on the study results until the study is reviewed and accepted.
4.2 Study Deliverables
4.2.1 The completed study shall be submitted as a single, paginated, sealed report containing the items required by the Deliverables section of this standard.
4.2.2 Draft versions of the study shall be submitted for review before equipment is released for manufacture.
4.3 Closeout Submittals
4.3.1 At substantial completion the Contractor shall submit:
- The final, sealed, stamped study report incorporating all field-verified data
- Native-format study files (importable into manufacturer-agnostic study software) for future re-studies
- A summary table of any equipment ratings that were field-verified and that differed from the design-basis ratings
- A re-study trigger list identifying the conditions under which the Owner should commission an updated study
☐ Final sealed, stamped study report with field-verified data
☑ Native-format study files for future re-studies
☑ Summary table of field-verified rating differences
☑ Re-study trigger list
5 Quality Assurance
● Commercial power system analysis software (manufacturer-agnostic)
○ Hand calculations per IEEE 551 (small systems only)
○ Combination — software with hand-calculation verification at key buses
5.1.1 The study shall be performed using a commercial power system analysis software package that implements the selected calculation standard (ANSI/IEEE or IEC) and that is in current commercial use by the industry.
5.1.2 The Contractor shall not specify or accept a software package by name; the requirement is that the package implement the selected standard correctly and that its results be verifiable by hand calculation at representative buses.
5.1.3 Hand-calculation-only studies may be used for very small systems where the number of buses is small enough that a software model adds no value.
NOTE For all other projects, software is required because it produces an auditable, re-runnable model that can be updated for future re-studies. (5.1.4)
5.2 Standard Identification
● ANSI/IEEE C37 (per IEEE 551)
○ IEC 60909
5.2.1 The ANSI/IEEE methodology is the default for projects in the United States and is required for any project where the installed equipment is rated by ANSI/IEEE standards (substantially all US-market low- and medium-voltage equipment).
5.2.2 IEC 60909 shall be used only where the project equipment is rated to IEC standards, where the project is located outside the United States in a jurisdiction that requires IEC, or where the Owner specifically directs.
5.2.3 The two methodologies produce different numerical results for the same physical system and are not interchangeable; the methodology shall be stated explicitly in the report.
5.3 Acceptance Criteria
5.3.1 The study shall be accepted by the Engineer of Record only when all of the following are documented:
- Every device intended to interrupt fault current has a documented interrupting rating equal to or greater than the calculated available fault current at its line terminals
- Every bus, busway, and switchgear assembly has a documented short-circuit withstand or short-circuit current rating equal to or greater than the calculated available fault current at its location, for the duration corresponding to the upstream protective device clearing time
- Every cable subject to fault current has been checked for short-circuit thermal capacity for the upstream device clearing time
- All deficiencies have been identified and a remediation plan submitted
5.3.2 Where the study identifies any device or bus that is under-rated for the available fault current, the Contractor shall submit a remediation proposal — current-limiting fuses, series-rated combinations, equipment replacement, or upstream impedance addition — for the Engineer's review before any affected equipment is energized.
6 Study Methodology
6.1 Calculation Points
6.1.1 The study shall calculate available short-circuit current at every bus, every transformer secondary, and at the line terminals of every device that is required to interrupt fault current or to withstand fault current without damage.
6.1.2 As a minimum, calculation points shall include:
- Utility service point and main service equipment line terminals
- Secondary of every power transformer (including dry-type distribution transformers)
- Line terminals of every switchboard, switchgear assembly, panelboard, and motor control center
- Line terminals of every motor starter, variable frequency drive, and other equipment whose short-circuit current rating must be verified
- Each significant feeder splice or tap point
- Each remote distribution panel and downstream lighting/appliance panel served from the system
☑ Utility service point
☐ Every transformer secondary
☐ Every switchboard, switchgear, MCC line terminals
☐ Every panelboard line terminals
☐ Every motor starter and VFD line terminals
☐ Significant feeder splices and tap points
☐ Branch-circuit panels
6.2 Fault Types
☑ Three-phase bolted fault (symmetrical, maximum)
☐ Line-to-line bolted fault
☐ Single line-to-ground bolted fault
☐ Three-phase fault — momentary (½ cycle)
☐ Three-phase fault — interrupting (1.5 to 4 cycles)
☐ Three-phase fault — time-delayed (30 cycles, where applicable)
NOTE A three-phase bolted fault produces the maximum symmetrical current at most points in a typical industrial or commercial system and is the controlling case for equipment interrupting rating and bus bracing. (6.2.1)
6.2.2 Line-to-ground faults shall be calculated and reported for systems with grounded sources, because in solidly grounded systems the single line-to-ground fault current can exceed the three-phase fault current at certain points.
6.2.3 Line-to-line faults shall be reported where required by the protective coordination study.
6.2.4 Per ANSI/IEEE methodology, three-phase fault currents shall be calculated at three time intervals: the first-cycle (momentary) value for bus bracing and instantaneous relay response, the interrupting (contact-parting) value at 1.5 to 4 cycles for medium- and high-voltage breaker interrupting ratings, and the time-delayed (30-cycle) value for time-delayed relay coordination.
6.2.5 For low-voltage systems the first-cycle value is the controlling value for both bus bracing and breaker interrupting rating per ANSI C37.13.
6.3 Impedance Modeling
● Manufacturer published impedances by conductor size and configuration
○ Typical values per IEEE 141 / IEEE 241
○ Field-measured cable lengths with calculated impedance
6.3.1 The system shall be modeled using positive, negative, and zero sequence impedances for every source, transformer, cable, and rotating machine.
6.3.2 Sequence impedances shall be obtained from equipment nameplates, manufacturer test reports, or — where measured data is unavailable — from the typical values published in IEEE 141, IEEE 241, or IEEE 399.
6.3.3 The use of typical values in lieu of measured data shall be explicitly noted in the assumption log for each affected component.
6.3.4 Cable impedances shall be calculated using the as-installed cable size, conductor material, raceway type (steel or non-magnetic), and route length.
6.3.5 The raceway material shall be modeled correctly per Raceways And Conduit and Conductors And Cables selections, because steel raceway produces higher reactance than non-magnetic raceway and the difference is significant for parallel-feeder systems. 6.4 Motor Contribution
○ All motors 50 HP and larger modeled individually
● All motors 50 HP and larger modeled individually; smaller motors lumped per bus
○ All motors lumped per bus by total connected HP
NOTE Motors contribute to fault current for the first several cycles after a fault because the inertia of the rotor acts as a temporary source. (6.4.1)
6.4.2 Motor contributions shall be modeled per IEEE 551 with subtransient reactance values from the motor nameplate or, where not available, from the typical values published in IEEE 551 by motor type and size.
NOTE Per the ANSI/IEEE methodology, induction motor contribution decays over the first several cycles and is represented by different impedance multipliers for the first-cycle, interrupting, and time-delayed networks. (6.4.3)
6.4.4 Motors smaller than 50 HP that are remote from the bus may be aggregated as a lumped motor contribution at the panel level, scaled by total connected horsepower.
6.4.5 Motors 50 HP and larger, all synchronous motors, and all motors served by adjustable-speed drives that can contribute regenerative current shall be modeled individually because their contribution to a nearby bus fault may be controlling for equipment selection.
6.4.6 Motor loads served entirely through current-limiting power electronics (most modern VFDs without regenerative front ends) do not contribute meaningful fault current and may be excluded from the contribution calculation.
6.4.7 The performer shall identify which motor loads are served entirely through current-limiting power electronics and shall document the basis for exclusion.
6.5 Utility Source Modeling
● Written confirmation from serving utility (preferred)
○ Worst-case estimate per utility published data
○ Infinite bus assumption (worst case where utility data unavailable)
0% — model exactly as provided by utility
10% — modest growth margin
25% — significant growth or interconnection planned
Per drawings
NOTE The utility's available short-circuit current at the service point is the single most important input to the study because the entire downstream system's fault duties scale with it. (6.5.1)
6.5.2 The Contractor shall request the available three-phase and single-line-to-ground short-circuit currents (with associated X/R ratios) from the serving utility in writing.
6.5.3 The Contractor shall include the utility's response, including any future expansion or interconnection allowances stated by the utility, as an appendix to the study report.
6.5.4 Where written utility data cannot be obtained before equipment procurement, the study shall use a conservative estimate documented as such.
6.5.5 An "infinite bus" assumption — modeling the utility as a source of unlimited current at its rated voltage — is the most conservative assumption and is acceptable as a worst-case basis.
6.5.6 The study report shall identify clearly which utility-source case was used and shall flag the study for re-execution if the actual utility value, when received, differs materially from the assumed value.
NOTE A future-expansion margin on the utility contribution is recommended because utility short-circuit values rise over time as the utility upgrades its system, and equipment installed today is expected to remain in service for thirty years or more. (6.5.7)
6.5.8 The future-expansion margin shall be a documented design decision, not a hidden assumption.
6.6 Generator and Standby Source Modeling
☑ Utility source only
☐ Standby source only
☐ Both sources paralleled (where momentarily paralleled during transfer)
☐ Generator paralleled with utility (cogeneration / peak shaving)
6.6.1 On-site sources — emergency generators, standby generators, and uninterruptible power supplies that can supply fault current — shall be modeled per IEEE 551.
6.6.2 The study shall calculate fault currents both with and without the standby source connected, because equipment downstream of an automatic transfer switch may see different available fault currents depending on which source is energized.
6.6.3 The higher of the with-source and without-source cases controls the equipment rating.
6.6.4 Where the system permits paralleled operation of utility and on-site generation, the parallel case shall be calculated explicitly and is normally the worst-case basis for downstream equipment.
NOTE The accuracy of the study output depends entirely on the accuracy of its inputs. (7.1)
7.2 The Contractor shall furnish, and the study performer shall document, every input value used.
7.3 Required Data
7.3.1 The following input data shall be obtained for each system component and shall be tabulated in the study report:
| Component |
Required Data |
| Utility service |
Three-phase and SLG available short-circuit currents and X/R ratios |
| Power transformers |
kVA rating, voltage ratings, impedance (%Z), X/R ratio, connection type |
| Distribution transformers |
Same as power transformers; manufacturer test report preferred |
| Generators |
kVA rating, subtransient/transient/synchronous reactances, X/R, time constants |
| Motors > 50 HP |
HP, voltage, locked-rotor or subtransient reactance, type (induction/synchronous) |
| Aggregated motors < 50 HP |
Total connected HP per bus, assumed average characteristics |
| Cables |
Size, material, length, raceway type, configuration (single/parallel) |
| Busway |
Manufacturer published impedance per foot, length |
| Circuit breakers |
Frame size, interrupting rating, voltage rating, manufacturer trip-unit data |
| Fuses |
Class, ampere rating, interrupting rating, current-limiting (I²t) data |
● Manufacturer nameplate / test reports (preferred)
○ Shop drawings
○ Field-measured / surveyed
○ Typical values per IEEE color books
7.3.2 Wherever a typical value is used in place of a measured or nameplate value, the substitution shall be flagged in the assumption log so that the Engineer of Record can assess the sensitivity of the study results to that assumption.
7.4 Existing Facility Surveys
○ Yes — survey of all equipment within study scope
● Yes — survey limited to equipment whose nameplate data is missing from drawings
○ No — drawings and submittals are complete
7.4.1 For studies that include existing equipment, the as-built configuration shall not be assumed from the original construction drawings, because equipment is routinely modified, replaced, and re-tapped over a facility's life without revisions to the drawings.
7.4.2 The Contractor shall perform a field survey of all existing equipment within the study scope, recording nameplate data, breaker frame sizes and trip settings, and cable sizes where visible.
7.4.3 Discrepancies between the field-surveyed condition and the existing drawings shall be reported to the Engineer.
8 Calculation Requirements
8.1 ANSI/IEEE Calculation Networks
8.1.1 For ANSI/IEEE methodology, the study shall calculate fault currents using the impedance multipliers and network adjustments of ANSI C37.010 and IEEE 551 for the following cases:
- First-cycle (momentary) network — for bus bracing, instantaneous protective device response, and low-voltage breaker interrupting rating per ANSI C37.13
- Interrupting (contact-parting) network — for medium-voltage breaker interrupting rating per ANSI C37.010, with contact parting time per the breaker rating
- Time-delayed (30-cycle) network — for time-delayed relay coordination per Protective Coordination Study
8.1.2 The same model shall be used for all three networks; the differences are in the impedance multipliers applied to rotating machines, not in the network topology.
8.2 IEC 60909 Calculation
8.2.1 Where IEC 60909 methodology is specified, the study shall calculate the initial symmetrical short-circuit current (I"k), peak short-circuit current (ip), symmetrical short-circuit breaking current (Ib), and steady-state short-circuit current (Ik) per IEC 60909-0.
8.2.2 Voltage factor c shall be applied per IEC 60909-0 Table 1 for the appropriate system voltage and case (maximum or minimum fault).
8.3 X/R Ratio and Asymmetry
● Applied where calculated X/R exceeds tested X/R per ANSI C37.010
○ Not applied — equipment selected with margin to envelope any X/R
8.3.1 The X/R ratio at each fault point shall be calculated separately from the magnitude of the symmetrical fault current.
NOTE The X/R ratio determines the dc component of the fault current and therefore the asymmetrical peak that equipment must withstand and interrupt. (8.3.2)
8.3.3 Where the calculated system X/R exceeds the tested X/R for a given device, an adjustment multiplier shall be applied per ANSI C37.010 or per the manufacturer's published derating data.
8.4 Pre-Fault Voltage
1.00 pu (rated voltage)
1.05 pu (high-voltage condition for maximum fault)
Per IEC 60909 voltage factor c (IEC methodology)
NOTE For ANSI/IEEE methodology, a pre-fault voltage of 1.00 per unit at the source is the standard assumption and produces results that are consistent with how equipment is tested. (8.4.1)
8.4.2 A higher pre-fault voltage (commonly 1.05 pu) may be specified where the system is known to operate above nominal voltage and a more conservative result is required.
8.4.3 The selected pre-fault voltage value shall be stated in the study report.
9 Equipment Rating Verification
NOTE The principal purpose of the short-circuit study is to verify that every device required to interrupt or withstand fault current has a rating equal to or greater than the calculated available fault current at its location. (9.1)
9.2 Interrupting Rating Verification
9.2.1 For every overcurrent protective device — main breakers, feeder breakers, branch breakers, fuses, and any other device whose function includes interrupting fault current — the study shall tabulate:
- Device identifier and location
- Manufacturer's interrupting rating at the applicable voltage
- Calculated available fault current at the device's line terminals
- Margin (manufacturer's rating minus calculated current), or deficiency where negative
- Pass / Fail / Pass-with-series-rating status
0% — exact equality is acceptable
10% — modest safety margin
25% — conservative margin for future growth
NOTE A device whose interrupting rating exactly equals the calculated available fault current technically complies with NEC 110.9 but provides no margin for utility-source growth, modeling uncertainty, or future system changes. (9.2.2)
9.2.3 A target interrupting-rating margin of at least 10 percent is recommended for new construction.
9.3 Series-Rated Combinations
○ Not permitted — every device must be fully rated
● Permitted only where tested combinations are explicitly listed by manufacturer
○ Permitted per NEC 240.86
NOTE A series-rated combination relies on the operation of an upstream device to limit the let-through current to a level the downstream device can interrupt. (9.3.1)
9.3.2 Series ratings are permitted by NEC 240.86 only where the combination has been tested and listed by the manufacturer and where labeled on the downstream equipment.
9.3.3 Series-rated combinations shall be reviewed in conjunction with the Protective Coordination Study before being accepted, because they introduce a coordination penalty in which the upstream device often must trip on faults that an independently rated downstream device would clear alone. 9.3.4 For service entrance equipment and for any system where selective coordination is required (life safety, healthcare, data centers), series ratings shall not be used.
9.4 Short-Circuit Withstand Rating
☑ Main switchgear / switchboard
☐ Distribution panelboards
☐ Motor control centers
☐ Busway runs
☐ Branch-circuit panelboards
9.4.1 For every bus, switchboard, switchgear assembly, motor control center, busway, and panelboard, the study shall verify that the assembly's short-circuit current rating or short-time withstand rating equals or exceeds the calculated available fault current.
9.4.2 For equipment with a short-time withstand rating (typically medium-voltage switchgear and low-voltage power circuit breaker switchgear per Low Voltage Switchgear), the withstand duration shall be at least as long as the upstream protective device's clearing time at the calculated fault current. 9.5 Cable Short-Circuit Withstand
9.5.1 Cables subject to high available fault current shall be checked for thermal short-circuit withstand using the I²t capacity of the conductor and the upstream device's let-through I²t.
9.5.2 The conductor shall be able to absorb the fault energy without exceeding the insulation's short-circuit temperature limit (typically 250 °C for thermoset insulations such as XHHW and XLPE).
NOTE For feeders protected by current-limiting fuses, the let-through I²t is significantly reduced and is published by the fuse manufacturer; for feeders protected by non-current-limiting breakers, the let-through energy is approximately the available current squared times the breaker's clearing time. (9.5.3)
9.6 Equipment Short-Circuit Current Rating (SCCR)
○ Required — every industrial control panel verified per UL 508A
● Required only for panels in scope of equipment furnished under this project
○ Not applicable — no industrial control panels in scope
NOTE NEC 409.110 requires industrial control panels to be marked with a Short-Circuit Current Rating (SCCR), which is the maximum available fault current the panel can withstand without damage. (9.6.1)
9.6.2 The study shall verify that every industrial control panel within the project scope has a labeled SCCR equal to or greater than the calculated available fault current at its line terminals.
9.6.3 Where a panel's SCCR is inadequate, the panel manufacturer shall be requested to provide a higher SCCR (typically achievable by changing branch components or adding upstream current-limiting protection) before the panel is installed.
10 Deliverables
10.1 Study Report Contents
10.1.1 The final study report shall be a single bound or paginated PDF document containing, in this order:
- Cover page with project identification, performer identification, date, revision history, and PE seal
- Executive summary stating the study scope, methodology, key findings, and any deficiencies identified
- System description with single-line diagram of the modeled system, with every bus and device identified
- Input data tables for all sources, transformers, motors, cables, and protective devices
- Assumption log enumerating every assumption made and the basis for it
- Calculation results — fault current and X/R at every bus, for every fault type calculated
- Equipment rating comparison tables (interrupting rating, withstand rating, SCCR)
- Deficiency findings with proposed remediation for each
- Recommendations for re-study and re-verification
- Appendices: utility correspondence, manufacturer data sheets, software input/output files
☐ Bound printed copy (sealed and signed)
☑ Sealed PDF (digitally signed by PE)
☐ Native study software files (.sav / .axd / .olr or equivalent)
☐ Editable single-line diagram (CAD or equivalent)
10.2 Single-Line Diagram
10.2.1 The single-line diagram included in the report shall show every modeled component with consistent identifiers, every transformer's kVA and impedance, every cable's size and length, and every bus's calculated three-phase and SLG fault current values shown adjacent to the bus.
10.2.2 The single-line diagram shall be legible at the printed page size; for large systems, the diagram may be subdivided across multiple sheets with cross-references.
10.2.3 The single-line diagram from the study shall be reconciled with the contract one-line diagram, and discrepancies between the study one-line and the construction documents shall be identified and resolved before the study is accepted.
10.3 Deficiency Reporting
● Tabular summary with per-deficiency remediation proposal
○ Tabular summary only (remediation handled separately)
10.3.1 Every device or assembly found to be under-rated for the calculated available fault current shall be reported individually, with location, calculated fault current, rated capability, and a proposed remediation.
10.3.2 The Contractor and Engineer shall jointly resolve each deficiency finding before the affected equipment is energized.
11 Re-Study Triggers
NOTE A short-circuit study reflects the system as it existed when the study was performed. (11.1)
11.2 The Owner shall commission an updated study whenever any of the following conditions occur, because each can change the calculated available fault current at one or more points in the system.
☑ Utility upgrade or change in available fault current at service
☐ Addition or removal of on-site generation or UPS
☐ Replacement or re-tapping of any power transformer
☐ Change in service or feeder conductor size, type, or length
☐ Addition of large motor loads (>50 HP) at any bus
☐ Major facility expansion or significant load addition
☐ Five-year periodic re-study (NFPA 70E recommendation)
NOTE The five-year periodic re-study aligns with the NFPA 70E recommended re-evaluation interval for arc flash analyses, which depend on short-circuit results; even where no facility change has occurred, utility source impedance commonly decreases over time as the utility upgrades its transmission and distribution system. (11.3)
11.4 The re-study trigger list shall be included in the closeout O&M manual so that future owners and facility managers know when to commission an updated study.
11.5 The Contractor shall provide field-marking of service equipment with the maximum available fault current and the date the marking was applied or verified, per NEC 110.24 and Equipment Labeling, using the study's service-point result. 12 Coordination with Other Studies
12.1 Protective Coordination Study
NOTE The protective coordination study (see
Protective Coordination Study) uses the short-circuit study's calculated fault currents and X/R ratios at every bus to verify that protective devices operate in the correct sequence for faults at every point in the system.
(12.1.1) 12.1.2 The short-circuit study and the protective coordination study shall be performed by the same engineering organization where practical, and any change to the short-circuit model shall trigger a corresponding update to the coordination study.
12.2 Arc Flash Study
NOTE The arc flash study (see
Arc Flash Study) uses the calculated bolted-fault currents from the short-circuit study and the device clearing times from the coordination study to calculate incident energy per IEEE 1584.
(12.2.1) 12.2.2 Arc flash results are derivative of short-circuit and coordination results; a change to either of those studies invalidates the arc flash labels and requires an arc flash re-study.
12.2.3 The three studies form a single, coupled analysis package and shall be managed as such.
12.3 Grounding and Bonding
NOTE The short-circuit study assumes that the grounding and bonding system establishes an effective ground-fault current path per
Grounding And Bonding, and the line-to-ground fault current calculated in the study is meaningful only to the extent that the installed grounding and bonding system actually provides the assumed return path.
(12.3.1) 12.3.2 Field verification of bonding continuity per Grounding And Bonding is a prerequisite to relying on the line-to-ground fault current results. 12.4 Field Acceptance Testing
12.4.1 The available fault current at the service shall be verified, where practical, during NETA acceptance testing per Low Voltage Switchgear and per ANSI/NETA ATS. 12.4.2 Verification methods include re-confirmation of the utility's stated available fault current at the time of energization and review of as-installed transformer and cable parameters against the study's modeled values.
12.4.3 Material discrepancies discovered during acceptance testing shall trigger a study revision before the equipment is placed in normal service.
13 Warranty
1 year — correction of errors at no additional cost
2 years — correction of errors at no additional cost
Per the engineer's standard professional services agreement
13.1 The study performer's professional engineering services shall be performed in accordance with generally accepted engineering practice and shall be warranted as such under the performer's professional liability coverage.
13.2 The Contractor shall provide the Owner with the engineer's contact information so that any future re-study, errata correction, or interpretation of the original study report can be addressed by the engineer of record for the study.
NOTE The errata period covers correction of calculation errors and reporting errors identified after delivery; it does not cover updates required by system changes, utility changes, or other re-study triggers, which are separately commissioned re-studies. (13.3)