1 Scope
NOTE This specification covers factory-fabricated, UL 508A listed industrial control panels and enclosures that house instrumentation and controls equipment for industrial, process, and water/wastewater facilities. (1.1)
NOTE An industrial control panel is an assembly of two or more power-circuit components, control-circuit components, or a combination of both, with associated wiring and terminals, mounted on a subpanel or in an enclosure, as defined by NFPA 70 Article 100. (1.2)
1.3Equipment shall be listed and labeled to UL 508A by a Nationally Recognized Testing Laboratory (NRTL) and shall bear the NRTL listing mark.
1.4The panel shall house the instrumentation and controls equipment indicated, which may include programmable logic controllers, remote input/output modules, control relays and timers, signal isolators and conditioners, power supplies, uninterruptible power supplies, network switches and media converters, and operator interface devices.
1.6Network equipment and the control network architecture served by the panel shall comply with Process Control Networks. NOTE A control panel is distinguished from a motor control center by the absence of a common power bus feeding plug-in motor starter units; control panels are built on a subpanel with point-to-point and wireway wiring, and where they include motor control it is limited to individually mounted starters or drives rather than a bussed assembly. (1.7)
NOTE Where the assembly is a bussed, floor-standing motor control center with plug-in starter units, see
Motor Control Centers rather than this standard.
(1.8) NOTE This standard governs the enclosure, the subpanel and component layout, internal power distribution, wiring and identification, thermal management, grounding, identification, and field installation of the panel as a listed assembly. (1.10)
2 Referenced Standards
NOTE Equipment, materials, and installation shall comply with the latest adopted edition of the following. (2.1)
| Standard |
Title |
| UL 508A |
Industrial Control Panels |
| UL 508 |
Industrial Control Equipment |
| UL 50 |
Enclosures for Electrical Equipment, Non-Environmental Considerations |
| UL 50E |
Enclosures for Electrical Equipment, Environmental Considerations |
| UL 489 |
Molded-Case Circuit Breakers, Molded-Case Switches, and Circuit-Breaker Enclosures |
| UL 98 |
Enclosed and Dead-Front Switches |
| UL 67 |
Panelboards |
| UL 1283 |
Electromagnetic Interference Filters |
| UL 1449 |
Surge Protective Devices |
| UL 5085-3 |
Low Voltage Transformers — Class 2 and Class 3 Transformers |
| UL 60947-4-1 |
Low-Voltage Switchgear and Controlgear — Contactors and Motor-Starters |
| NFPA 70 |
National Electrical Code (Article 409 — Industrial Control Panels; Article 110 — Requirements for Electrical Installations) |
| NFPA 79 |
Electrical Standard for Industrial Machinery |
| NFPA 70E |
Standard for Electrical Safety in the Workplace |
| NEMA 250 |
Enclosures for Electrical Equipment (1000 Volts Maximum) |
| NEMA ICS 6 |
Industrial Control and Systems: Enclosures |
| NEMA ICS 2 |
Industrial Control and Systems: Controllers, Contactors, and Overload Relays |
| ANSI/ISA-5.1 |
Instrumentation Symbols and Identification |
| ANSI/ISA-TR20.00.01 |
Specification Forms for Process Measurement and Control Instruments |
| IEEE 1584 |
Guide for Performing Arc-Flash Hazard Calculations |
| IEEE 518 |
Guide for the Installation of Electrical Equipment to Minimize Electrical Noise Inputs to Controllers |
| IEC 61439-1 |
Low-Voltage Switchgear and Controlgear Assemblies — General Rules |
| IEC 61439-2 |
Low-Voltage Switchgear and Controlgear Assemblies — Power Switchgear and Controlgear Assemblies |
| IEC 60529 |
Degrees of Protection Provided by Enclosures (IP Code) |
| IBC |
International Building Code (seismic provisions) |
| ASCE 7 |
Minimum Design Loads and Associated Criteria for Buildings and Other Structures |
| ICC ES AC156 |
Acceptance Criteria for Seismic Certification by Shake-Table Testing of Nonstructural Components |
2.2Where 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.
3 Submittals
3.1 Action Submittals
3.1.1Contractor shall submit the following for the Engineer's review and approval prior to fabrication:
- Enclosure data sheet identifying the type rating, material, dimensions, mounting configuration, and listing
- Bill of materials listing every power-circuit and control-circuit component by function, with manufacturer catalog data
- Subpanel layout drawing showing the physical arrangement of all components, wireways, terminal blocks, and required spacings
- Power distribution single-line diagram showing the main disconnect, branch protection, control power transformer, and power supplies
- Ladder (elementary) and connection (wiring) diagrams using ANSI/ISA-5.1 symbols and a consistent wire-numbering scheme
- SCCR determination documentation prepared per UL 508A Supplement SB, identifying the limiting component and the marked panel SCCR
- Thermal load calculation showing total internal heat dissipation, the selected cooling or heating method, and the maintained internal temperature
- Nameplate and wire-marker schedule
- Arc-flash and field-wiring terminal schedules with available fault current and clearing-time inputs where furnished by the Engineer
☐ Enclosure data sheet (type rating, material, dimensions, listing)
☐ Bill of materials with component catalog data
☐ Subpanel layout drawing
☐ Power distribution single-line diagram
☐ Ladder and connection (wiring) diagrams
☐ SCCR determination per UL 508A Supplement SB
☐ Thermal load calculation and cooling/heating selection
☐ Nameplate and wire-marker schedule
☐ Arc-flash and field-wiring terminal schedules
3.1.2Fabrication shall not proceed until submittals are reviewed and returned.
3.2 Closeout Submittals
3.2.1Contractor shall provide at substantial completion:
- Operation and maintenance manuals, bound, with component data, configuration records, and recommended maintenance intervals
- As-built ladder and connection diagrams reflecting all field modifications and final wire numbers
- Factory and field test reports, including the production dielectric and continuity tests and the field functional checkout
- Final SCCR determination and the documented available fault current at the point of installation per NEC 409.22
- Loaded spare-parts inventory with manufacturer part numbers and reorder information
- Warranty documentation listing the panel serial number, installation date, and warranty expiration
☐ Operation and maintenance manuals (bound)
☐ As-built ladder and connection diagrams
☐ Factory and field test reports
☐ Final SCCR and documented available fault current (NEC 409.22)
☐ Spare-parts inventory with part numbers
☐ Warranty documentation (serial number and dates)
4 Quality Assurance
4.1 Manufacturer Qualifications
4.1.1Panels shall be fabricated by a UL 508A listed panel shop operating under an active NRTL certification with authority to apply the UL 508A listing mark.
4.1.2The panel shop shall have a minimum of five years documented experience fabricating UL 508A listed control panels for industrial or water/wastewater service.
4.1.3The individual responsible for the SCCR determination shall be qualified under the panel shop's UL 508A program, and where the contract documents require it, the determination shall be reviewed and stamped by a registered Professional Engineer.
4.2 Source Limitations
4.2.1The enclosure, subpanel, and all factory-installed components shall be furnished and assembled by the listed panel shop as a single listed assembly bearing one UL 508A mark.
NOTE Field modification that adds or relocates power-circuit components after listing shall not be performed unless the modification is made under the panel shop's listing or re-evaluated by the NRTL, because such modification can void the marked SCCR and the listing. (4.2.2)
4.3 Component Listings
4.3.1Every component installed in the panel shall be listed or recognized for its application by an NRTL.
4.3.2Field-installed wiring devices, terminal blocks, and overcurrent devices shall be listed and applied within their listed ratings.
5 Environmental and Service Conditions
NOTE The panel shall be suitable for continuous operation under the ambient conditions at its installed location. (5.1)
NOTE Where site conditions exceed the values selected below, notify the manufacturer so the enclosure type, thermal management, and component derating can be confirmed. (5.2)
Indoor, climate-controlled control room
Indoor, unconditioned process or electrical room
Outdoor, sheltered
Outdoor, exposed
Washdown / wet process area
Corrosive process area (chemical feed, headworks, digester)
40°C (standard rating)
50°C (unconditioned indoor)
55°C (outdoor or process heat exposure)
C2 - Low (indoor, climate-controlled)
C3 - Medium (indoor, unconditioned)
C4 - High (industrial, coastal, water/wastewater)
C5 - Very High (chemical feed, headworks, marine)
5.3Component continuous ratings are established at a 40°C reference ambient; where the maintained internal enclosure temperature exceeds this reference, components shall be derated per their published tables.
5.4Water and wastewater environments are routinely classified C4 or higher because of chlorine, hydrogen sulfide, and washdown exposure; enclosure material and finish shall be selected for the corrosion severity at the specific installed location rather than a facility-wide default.
5.5For chemical feed rooms, headworks, and digester areas classified C5, the manufacturer shall confirm enclosure material suitability for the specific corrosive exposure and submit that confirmation with shop drawings.
6 Enclosure
6.1 Type Rating
NOTE Enclosure type rating shall be as indicated for the installed environment and shall be listed to UL 50 and UL 50E for the marked type. (6.1.1)
Type 1 - Indoor, general purpose
Type 12 - Indoor, dust-tight and drip-tight
Type 3R - Outdoor, rain and ice
Type 4 - Indoor/outdoor, watertight and dust-tight (washdown)
Type 4X - Watertight, dust-tight, corrosion-resistant
NOTE Type 1 enclosures provide protection against incidental contact and falling dirt only and are limited to clean, climate-controlled indoor control rooms. (6.1.2)
NOTE Type 12 is the most common indoor industrial rating, excluding circulating dust, falling dirt, and dripping non-corrosive liquids, and is the default for unconditioned process and electrical rooms. (6.1.3)
NOTE Type 4 adds protection against hose-directed water and is required in washdown areas; Type 4X adds corrosion resistance and is required wherever the environment is classified C4 or higher. (6.1.4)
NOTE A NEMA or UL type rating is not equivalent to an IEC 60529 IP code; type ratings include corrosion, oil, gasket-aging, and construction requirements that IP codes do not address, so an IP-only enclosure shall not be substituted for a marked type rating. (6.1.5)
6.2 Material and Finish
Painted steel (powder-coat)
Type 304 stainless steel
Type 316 / 316L stainless steel
Fiberglass-reinforced polyester (FRP)
Non-metallic (polycarbonate)
NOTE Painted steel is the standard material for indoor Type 1 and Type 12 enclosures in non-corrosive environments. (6.2.1)
6.2.2Type 304 stainless steel shall be used for outdoor and washdown Type 4/4X enclosures in moderately corrosive (C4) environments.
6.2.3Type 316 or 316L stainless steel shall be used in chloride-bearing and severely corrosive (C5) environments, including chemical feed rooms, headworks, and coastal installations, because 304 stainless suffers pitting and chloride stress-corrosion cracking in these exposures.
6.2.4Fiberglass-reinforced polyester or non-metallic enclosures may be used where the environment is corrosive but the housed equipment does not require the electromagnetic shielding of a metallic enclosure.
NOTE Non-metallic enclosures shall not be used where the housed equipment requires a continuous metallic ground reference plane or shielding against electrical noise. (6.2.5)
6.2.6Painted steel enclosures shall receive a minimum two-coat system of corrosion-resistant primer and polyester powder-coat finish with a minimum 3 mil (75 µm) total dry film thickness.
6.3 Construction
Wall-mount
Free-standing floor-mount (single door)
Free-standing floor-mount (multi-door / multi-bay)
Console / operator workstation
Single hinged door
Double hinged doors
Hinged door with inner swing-out panel
6.3.2Doors shall be hinged, gasketed where the type rating requires, and fitted with a three-point latching mechanism on doors exceeding 48 in. in height to maintain the gasket seal across the full door.
6.3.3A removable or hinged subpanel finished with a conductive or paintable surface shall be provided for mounting components; components shall not be mounted to the enclosure walls or door except for operator interface and pilot devices.
6.3.4Door-mounted devices shall be sealed to maintain the enclosure type rating, and conductors crossing the hinge shall be protected with a flexible hinge-wire harness or spiral wrap rated for repeated flexing.
6.3.5Print pockets shall be provided on the inside of each door to hold the as-built wiring diagrams.
7 Power Distribution
7.1 Incoming Service
120V 1-Phase
240V 1-Phase
208Y/120V 3-Phase 4-Wire
480Y/277V 3-Phase 4-Wire
480V 3-Phase 3-Wire
Door-interlocked rotary disconnect switch
Main circuit breaker (flange-mounted operator)
Terminal block only (disconnect provided upstream)
7.1.1A main disconnecting means shall be provided within or ahead of the panel such that all power circuits can be de-energized for maintenance, and where the disconnect is within the panel its operator shall be interlocked with the door.
7.1.2Branch-circuit overcurrent protection shall be provided for each control power transformer, power supply, and feeder tap within the panel, listed and sized per NFPA 70 Article 409 and the component manufacturer's instructions.
7.2 Short-Circuit Current Rating
NOTE The panel short-circuit current rating shall equal or exceed the available fault current at the point of installation, as required by NFPA 70 Article 409.22. (7.2.1)
5 kA
10 kA
14 kA
18 kA
22 kA
25 kA
42 kA
65 kA
100 kA
7.2.3The SCCR shall be determined by the analytical method of UL 508A Supplement SB and shall be marked on the panel nameplate per NEC 409.110.
NOTE The panel SCCR is limited by the weakest link in the power circuit, which is the lowest individual component short-circuit current rating or the lowest interrupting rating of an overcurrent protective device after current-limiting and feeder-circuit adjustments are applied. (7.2.4)
7.2.5Components in the power circuit that lack a marked SCCR shall be assigned the default rating from UL 508A Supplement SB Table SB4.1 for the SCCR determination.
7.2.6Where the determined SCCR is below the available fault current, the rating shall be raised before fabrication by applying a current-limiting protective device, selecting higher-rated components, or applying the feeder-circuit method of Supplement SB4.3.
NOTE The feeder-circuit method limits the let-through energy ahead of the branch components using a current-limiting device located entirely in the feeder circuit; that device shall not be relied upon for branch-circuit protection. (7.2.7)
NOTE A control panel SCCR is a frequent inspection and RFI failure point; many off-the-shelf components default to 5 kA, which is below the available fault current at typical service entrances, so the determination shall be performed during design rather than assumed. (7.2.8)
Control power transformer (line voltage to 120V AC)
Direct 120V AC supply (no transformer)
Low-voltage DC power supply only
120V AC
24V DC
120V AC and 24V DC
7.3.1Where the incoming supply exceeds 120V, a control power transformer shall step the supply down to the AC control voltage, and the transformer shall be sized for the connected control load plus a minimum 25% spare capacity.
7.3.2The control power transformer shall have primary and secondary overcurrent protection per NFPA 70 Article 450, and one secondary leg shall be grounded where required by NFPA 79.
7.3.3A regulated DC power supply shall be provided for the 24V DC control and instrument loop power, sized for the connected load plus 25% spare capacity, and shall be fused on its output.
7.3.4Where loss of control power would interrupt a critical process, an uninterruptible power supply or redundant supply arrangement shall be provided as indicated.
NOTE Instrument loop power and PLC I/O are commonly 24V DC while pilot devices and motor control are 120V AC; providing both from segregated, individually fused sources prevents a single fault from collapsing the entire control system. (7.3.5)
8 Component Layout and Spacing
NOTE Components shall be arranged on the subpanel to maintain the spacing through air and over surfaces required by UL 508A between live parts of opposite polarity and between live parts and grounded metal. (8.1)
8.2Heat-producing components, including transformers, power supplies, and drives, shall be mounted low and toward the rear of the enclosure, with temperature-sensitive components mounted away from them, to manage the internal thermal gradient.
8.3A minimum manufacturer-specified clearance shall be maintained around each component for ventilation and for the bending radius of connected conductors.
8.4Operator interface devices, pilot lights, and selector switches shall be mounted on the door or a dead-front at an accessible height, sealed to maintain the enclosure type rating.
8.5Spare mounting space and spare DIN-rail length of not less than 20% of the populated area shall be provided for future component additions.
9 Wiring and Identification
9.1 Power and Signal Segregation
NOTE Power wiring and control or signal wiring shall be routed in separate wireways and shall not share a common wireway or be bundled together. (9.1.1)
9.1.2Where power and signal conductors must cross, they shall cross at right angles to minimize coupling.
9.1.3Analog and instrument signal cabling shall be shielded, with the shield grounded at one end only per IEEE 518, to limit electrical noise on low-level signals.
9.1.4A minimum separation of 1 in. shall be maintained between parallel runs of power wiring and signal wiring, increasing the separation where higher-energy or drive output circuits are present.
NOTE Variable frequency drive output conductors, where present, shall be routed in dedicated wireways or shielded cable separated from all control and signal wiring, because drive output carries high-frequency switching noise that couples readily into instrument circuits. (9.1.5)
9.2 Conductors
9.2.1Internal power-circuit conductors shall be not smaller than 14 AWG, stranded, with insulation listed for the application.
9.2.2Internal control-circuit conductors shall be not smaller than 18 AWG, stranded, except that PLC and instrument I/O conductors may be smaller where listed for the device terminal.
9.2.3Conductors shall be sized for the connected load with no point in the wiring exceeding the ampacity allowed for the conductor and its termination.
9.3 Wire Color Coding
NOTE Internal wiring shall follow the NFPA 79 color convention so that the source and voltage of any conductor are identifiable during maintenance. (9.3.1)
| Color |
Circuit |
| Black |
Ungrounded AC power conductors |
| Red |
Ungrounded AC control conductors |
| Blue |
Ungrounded DC control conductors |
| Orange |
Conductors that remain energized when the panel disconnect is open (foreign / external source) |
| White or natural gray |
Grounded (neutral) AC conductors |
| White with blue stripe |
Grounded DC conductors |
| Green or green with yellow stripe |
Equipment grounding (protective) conductors |
NOTE Orange conductors shall identify every circuit that is not de-energized by the panel main disconnect, so that maintenance personnel are warned of voltage present after lockout of the main disconnect. (9.3.2)
9.4 Wire and Terminal Identification
9.4.1Every conductor shall be marked at both ends with a permanent wire marker bearing a unique wire number that matches the connection diagram.
9.4.2Terminal blocks shall be DIN-rail mounted, of the screw-clamp or spring-clamp type, individually marked, and grouped by function with power, control, and signal terminals in separate groups.
9.4.3Field-wiring terminals shall be segregated from internal-wiring terminals and grouped so that all field connections of a given type are made at a contiguous block.
9.4.4Not more than one conductor shall be terminated under a single terminal screw unless the terminal is listed for multiple conductors.
9.4.5A minimum of 20% spare terminals shall be provided in each field-wiring terminal group for future connections.
9.4.6Analog signal terminals shall be fused or fitted with disconnect-style terminal blocks to allow individual loop isolation for calibration and troubleshooting.
10 Thermal Management
NOTE The internal enclosure temperature shall be maintained within the operating range of the housed components, which is commonly 0°C to 50°C, under the maximum external ambient and full internal heat load. (10.1)
10.2 Heat Load
10.2.1The manufacturer shall calculate the total internal heat load as the sum of the heat dissipated by all housed components plus, for sealed enclosures, the heat transferred through the enclosure walls from the external ambient.
NOTE Component heat dissipation in watts shall be converted to BTU/hr by multiplying by 3.412 where the cooling equipment is rated in BTU/hr. (10.2.2)
10.2.3The thermal calculation shall account for solar heat gain on outdoor enclosures and for the reduced dissipation surface of enclosures mounted against a wall or grouped together.
10.3 Cooling Method
Natural convection (sealed, no active cooling)
Filtered fan and vent (Type 12 indoor)
Air-to-air heat exchanger (sealed)
Closed-loop air conditioner (sealed)
Vortex cooler (compressed air)
10.3.1Natural convection is adequate only where the calculated heat load can be rejected through the enclosure walls without exceeding the maximum internal temperature.
10.3.2Filtered fans with intake and exhaust vents may be used only in Type 12 indoor environments where the ambient air is clean and cool; filters shall be listed to UL 1283 and shall be accessible for replacement without opening the enclosure.
NOTE A filtered-fan ventilation scheme shall not be used on a Type 4, 4X, or outdoor enclosure, because it breaches the watertight and corrosion-resistant rating; sealed cooling by air-to-air heat exchanger, closed-loop air conditioner, or vortex cooler shall be used instead. (10.3.3)
10.3.4A closed-loop air conditioner shall be used where the internal heat load cannot be rejected to the ambient by a heat exchanger, such as where the external ambient approaches or exceeds the maximum allowable internal temperature.
NOTE An air-to-air heat exchanger is preferred over an air conditioner where the external ambient is reliably several degrees below the target internal temperature, because it has no refrigeration circuit to maintain and no condensate to manage. (10.3.5)
10.3.6Cooling equipment shall maintain the enclosure type rating at its mounting penetration and shall be sized with margin above the calculated heat load.
10.4 Condensation and Heating
None required (climate-controlled indoor)
Thermostat-controlled space heater
Space heater with humidistat
10.4.1A thermostat-controlled enclosure space heater shall be provided in outdoor and unconditioned enclosures to keep the internal temperature above the dew point and prevent condensation on electronic components.
10.4.2Condensate from any active cooling equipment shall be drained or evaporated without dripping onto live parts.
10.4.3Outdoor enclosures shall be furnished with a drain and breather fitting that relieves pressure differentials while excluding water and insects, sized for the enclosure volume.
11 Grounding and Bonding
NOTE A grounding terminal or bar shall be provided in the enclosure and bonded to the subpanel and to all non-current-carrying metal parts. (11.1)
11.2The enclosure grounding terminal shall be connected to the facility grounding system per Grounding And Bonding. 11.3Door-mounted and hinged-panel metal shall be bonded to the enclosure body with a flexible bonding jumper; reliance on the hinge for ground continuity is not acceptable.
11.4A separate, insulated instrument-reference (clean) ground bar shall be provided where the housed instrumentation requires an isolated signal ground, connected to the grounding system at a single point per IEEE 518 to avoid ground loops on analog signals.
NOTE Shield-drain conductors for analog signal cables shall land on the instrument-reference ground bar at the single grounding point, not on the equipment grounding bar. (11.5)
12 Identification
12.1 Nameplates
NOTE The panel shall bear a permanent manufacturer nameplate stating the listing, supply voltage, full-load current, short-circuit current rating, and the date of the SCCR determination, as required by NFPA 70 Article 409.110. (12.1.1)
12.1.2Engraved laminated-phenolic or stainless-steel nameplates shall identify the panel designation, each operator device, and each major component, with legends matching the contract drawings and the control descriptions.
○ Laminated phenolic (indoor)
○ Stainless steel (outdoor or corrosive)
12.1.3Component nameplates and device legends shall match the tag numbers shown on the ANSI/ISA-5.1 loop and ladder diagrams so that a device can be traced between the panel, the drawings, and the field instrument.
12.2 Arc-Flash Labeling
12.2.1An arc-flash warning label shall be applied to the panel per NFPA 70E and NFPA 70 Article 110.16, identifying the incident energy or required PPE category, the arc-flash boundary, and the available fault current.
13 Testing
13.1 Factory Tests
NOTE The panel shop shall perform the following production tests on the completed panel before shipment: (13.1.1)
- Dielectric withstand (hipot) test of the power circuit per UL 508A
- Continuity and point-to-point verification of all wiring against the connection diagram
- Functional test of control circuits, interlocks, and operator devices using simulated inputs where practical
- Verification of grounding continuity from the grounding terminal to each component and door
- Confirmation that the marked SCCR, voltage, and current on the nameplate match the as-built assembly
○ Witnessed by Owner's representative
○ Unwitnessed with certified test report
○ Standard production tests only
13.1.2Where a witnessed factory acceptance test is specified, the manufacturer shall provide a minimum of two weeks advance notice and shall submit the test procedure for review prior to testing.
13.2 Field Tests
NOTE After installation and before placing the panel in service, the Contractor shall verify the following: (13.2.1)
- The available fault current at the installed location does not exceed the marked panel SCCR
- All field-wiring terminations are landed per the connection diagram and torqued to the manufacturer's values with a calibrated tool
- Grounding and bonding connections to the facility grounding system are complete and continuous
- Control power and DC supplies are present and at the correct voltage
- Functional checkout of every input and output to the connected field devices and the control system
○ Full loop check (every I/O point to field device)
○ Panel functional test only (simulated I/O)
14 Installation
14.1 Mounting
14.1.2Wall-mounted panels shall be mounted on corrosion-resistant struts or stand-offs that hold the enclosure off the wall surface to allow air circulation and prevent trapped moisture behind the enclosure.
14.1.3Free-standing panels shall be mounted on a concrete housekeeping pad raised a minimum of 4 in. above the finished floor for indoor installations and 6 in. above finished grade for outdoor installations.
14.1.4Anchorage shall be designed for the seismic and wind loads required by the building code where applicable.
14.2 Working Clearance
14.2.1Working space in front of the panel shall be maintained per NFPA 70 Article 110.26 for the supply voltage and shall not be used for storage.
| Voltage |
Condition 1 (clear on one side) |
Condition 2 (grounded surface opposite) |
| 0-150V |
36 in. |
36 in. |
| 151-600V |
36 in. |
42 in. |
14.3 Conduit Entry
○ Bottom entry
○ Top entry
○ Bottom and top entry
14.3.1Conduit entries shall be located to maintain the enclosure type rating, using listed hubs and fittings of the same type rating as the enclosure.
14.3.2For Type 4, 4X, and outdoor enclosures, conduit shall enter the bottom of the enclosure wherever possible, and all penetrations shall be sealed with listed watertight fittings.
14.3.3Conduit seals shall be provided where required to prevent the migration of moisture, corrosive vapors, or condensation from the raceway into the enclosure.
15 Delivery, Storage, and Handling
15.1Panels shall be shipped factory-assembled and tested, protected against physical damage and moisture during transit.
15.2Lifting provisions shall be provided on free-standing panels, and the Contractor shall verify pathway dimensions between the delivery point and final location before delivery.
15.3Panels shall be stored indoors in a clean, dry location until installation; where the storage environment is not climate-controlled, enclosure heaters shall be energized during storage to prevent condensation.
16 Warranty
1 year from substantial completion
2 years from substantial completion
3 years from substantial completion
16.1Warranty shall cover defects in materials and workmanship of the panel assembly, including the enclosure, wiring, and factory-installed components, under normal use and service conditions.
16.2The manufacturer shall maintain a service organization capable of furnishing replacement components and documentation during the warranty period.
17 Spare Parts
☐ One spare control relay of each type installed
☐ One spare power supply of each rating installed
☐ One spare control fuse of each rating installed
☐ One spare signal isolator / conditioner of each type installed
☐ One spare pilot light lens and lamp of each color installed
☐ One spare cooling fan and filter set (where fans are installed)
17.1Spare parts shall be of the same type, rating, and configuration as the installed components and shall be delivered in labeled packaging with the closeout documentation.
17.2A spare DC power supply shall be provided where the panel serves a critical process and loss of control power would interrupt operation.