Thursday, May 3, 2018

Certified Master Electrical Code Professional Program

Introducing Electrical Code Academy's Certified Master Electrical Code Professional ™ (CMECP™) program and the differences in licensing versus certification.

The term certification is often used as a catch-all term for several different activities that apply to the credentialing of individuals and institutions in the electrical profession. The lack of clarity in this definition has resulted in confusion when it comes to discussing credentials.
Certification is essentially the process of publicly attesting that a specified quality or standard has been achieved or exceeded. We see this in an informal way all around us nearly every day. For example, when a product has the Good Housekeeping Seal of Approval, it means that the item has been attested to meet the standard set for it. Whenever we make a recommendation or referral to a colleague or client we are informally certifying the competence of the person or the quality of the item being recommended.
Professional certification uses a formal process to identify and acknowledge individuals who have met a recognized standard, such as the Certified Master Electrical Code Professional program. Usually this standard includes education, experience, and an exam of knowledge, skills, and abilities needed to obtain the professional designation. When an individual meets the standard, he or she receives certification from a certifying agency, such as the Electrical Code Academy, Inc. CMECP™ Advisory Board. Generally, this standard involves the qualification requirements to take the exam, whether the exam meets accepted standards for exam development, how the exam is given and scored, how the agency is administered, and whether its rules are fair.
Professional certification is a voluntary process by which a non-governmental professional organization grants recognition to an individual who has met certain strict qualifications. It is a credential which attests that the individual has demonstrated a certain level of mastery of a specific body of knowledge and skills within the relevant field of practice, such as the National Electrical Code®. Certification should not be confused with either licensing or accreditation. While each involves some type of evaluation and the awarding of some type of credential, they are quite different from one another and the terms should not be used interchangeably.
Licensing is a non-voluntary process by which an agency of government regulates a profession. It grants permission to an individual to engage in an occupation if it finds that the applicant has attained the degree of competency required to ensure the public health, safety, and welfare will be reasonably protected. Licensing it always based on the action of a legislative body. Once a licensing law has been passed it becomes illegal for anyone to engage in that occupation unless he or she has a license. The CMECP™ designation is not a license but a certification and should not be construed as licensing.
Certification differs from licensing in that it is nearly always offered by a private, non-governmental agency or corporation. Such agencies or corporations create certifying agencies to identify and acknowledge those who have met a specific standard of excellence. Another contrast with licensure is that, under a licensing law, practitioners of the licensed occupation must have a license in order to practice. It is involuntary. On the other hand, certification is 100% voluntary. One does not have to be certified in order to practice. An individual takes the certification exam because they want to enjoy the benefits of certification. However, to use the title and initials copyrighted and associated with the professional certification, one must be certified.
Accreditation is a non-governmental, voluntary process that evaluates institutions, agencies, and educational programs, (i.e., institutions that grant certificates or diplomas) while certification and licensing involves individual practitioners. Accreditation is defined as the process whereby an agency or association grants public recognition to a school, institute, college, university, or specialized program of study for having met certain established qualifications or standards as determined through initial and periodic evaluations that usually involve submitting a self-evaluation report, site inspection by a team of experts, and evaluation by an independent board or commission.
The Certified Master Electrical Code Professional [CMECP™] certification was founded by Electrical Code Academy, Inc., a Texas Corporation, to facilitate a higher degree of professionalism and code of ethics to the master electrical code professional. The overall goals of the certification program is to help foster and acknowledge an advanced level of knowledge, training and commitment to the understanding, development, interpretation and implementation of the National Electrical Code® by licensed Master Electricians.
The certification process for becoming a CMECP™ is a rigorous journey. The candidate must pass (1) prerequisite course on Electrical Exam Prep Review in order to solidify their understanding of the National Electrical Code® and (1) prerequisite continuing education course for the state where their Master Electrician license is registered. Once completed the candidate is required to attend a 6 hour "Navigating The NEC" webinar where they will learn all the in's and out's of the National Electrical Code® by current and former NFPA70® (NEC®) Code Making Panel members. Upon completion of the mandatory webinar the candidate will be required to take a written exam with a passing score of 80%.
Candidates that make it to the last stage of the certification process will be invited to a video conference call attended by 5 members of the CMECP™ Candidate Review Board. Each member of the review board will ask the candidate a National Electrical Code® question to which the candidate must respond, this is an open book interview. If the question is answered to the satisfaction of the board member the candidate will move to the next member of the board for a subsequent question. The candidate will only need to satisfy 2/3rd of the panel to compete the final phase and earn the designation of CMECP™.
In conclusion, The CMECP™ program is the only one of it's kind dedicated to the National Electrical Code® and Master Electricians. The unique 5-step approval process will without a doubt be the hardest approval process any Master Electrician will ever face. The Master Electrician who earns the designation of CMECP™ can hold their head up high with pride knowing that they are part of a unique group of professional Master Electricians who took their game to the next level and became a true Certified Master Electrical Code Professional™.
For more information on the CMECP™ program please visit
Paul W Abernathy, CMI, CMECP™
NEC®, NFPA®, NFPA70®, National Electrical Code® are all registered trademarks of the National Fire Protection Association. These terms are used for educational purposes only and in no way imply that Electrical Code Academy, Inc. or the CMECP™ program is part of or affiliated with or endorsed by the NFPA.

Tuesday, April 24, 2018

Type MC Cable in Environmental Air Spaces per 2017 NEC 300.22(C)

Is Metal-Clad Cable “Plenum” Rated?

NEC Section 300.21 provides clarification to the intend of why the concern about ratings of raceways or cables assemblies for electrical installations in hollow spaces, vertical shafts, and ventilation or air-handling ducts be made so the possible spread of fire or products of combustion, such as smoke, will not be substantially increased. Even before we can begin to determine the various wiring methods that can be utilized in ducts, plenums, or other air-handling spaces, it is critical to fully understand the terminology used when dealing with air-handing systems.

An air distribution system is defined as a continuous passageway for the transmission of air. This distribution system can consist of air ducts, air connectors, duct fittings, dampers, plenums, fans, and accessory air-handling equipment. An air duct is defined as a conduit for conveying air. Environmental air is air that is supplied, returned, re-circulated, or exhausted from spaces for the purpose of modifying the existing atmosphere within the building. A plenum is defined in NFPA 90A as a compartment or chamber to which one or more air ducts are connected that form part of the closed air distribution system. A plenum cannot be used as an occupied space or for storage of any materials. Article 100 of the NEC provides the same definition for plenum as that found in NFPA 90A.

The word “plenum” in the NEC is used to describe both an air space and also various types of wiring methods that are specifically designed and tested for installation within these areas. Section 300.22(A) of the NEC provides information on the installation and uses of electrical wiring and equipment in ducts that are used to transport dust, loose stock, or flammable vapors. These ducts can be used for vapor removal or for ventilation of commercial-type cooking equipment as referenced in the section. These ducts can be connected into a larger vertical or horizontal shaft or can be installed as a single duct without a shaft connection. No wiring or electrical equipment can be installed in these ducts. Ironically, lighting luminaries are permitted in the commercial cooking hood where they meet all of the conditions stated in Section 410.10(C).

Section 300.22(B) provides requirements for ducts or plenums “specifically fabricated for environmental air”. These ducts or plenums, such as metal or fiberglass ducts, pre-constructed or assembled on-site are again dedicated to those specifically fabricated to transport environmental air in a closed system with ducted supply and return ducts. Under section 300.22(B) the wiring methods permitted are Rigid Metal Conduit (RMC), Intermediate Metal Conduit (IMC), Electrical Metallic Tubing (EMT), Mineral Insulated cable (MI cable), and Metal-Clad Cable (Type MC cable) employing a smooth or corrugated impervious metal sheath without a nonmetallic covering can be used for wiring within these fabricated ducts or plenums.

Electrical equipment and devices are permitted within these ducts or chambers only if they are needed for the direct action on or sensing of the air contained within the duct. Flexible metal conduit (Type FMC) can be used within fabricated ducts to connect adjustable equipment and similar devices but are limited to (4) four feet. If illumination is required inside the fabricated duct to assist in maintenance and repair of equipment located within the duct, an enclosed and gasketed fixture must be used. This would restrict standard interlocked type Metal-Clad Cable in these “specifically fabricated environmental ducts.

However, an exception was added in the 2017 NEC to permit any of the wiring methods found in 300.22(C)(1), such as Interlocked type Metal-Clad Cable for use inside of a “specifically fabricated environmental duct” where necessary to supply equipment or a device located inside the duct that has a direct action upon or sensing of the contained air. This exception also limits the total length of the wiring method or cable assembly to not more than (4) four feet. It is important to not get confused by this exception. Interlocked Metal-Clad Cable is only allowed if a specifically fabricated duct “Plenum” to supply items such as smoke alarm, airflow sensor, or other listed equipment installed inside the fabricated duct.

Now lets examine section 300.22(C) as this is where things change for Interlocked Metal-Clad Cable (Type MC Cable). An “other space used for environmental air” covered in section 300.22(C) is one that is not specifically fabricated for environmental air but is used for transportation of either supply or return air. For example, the space over a dropped or suspended ceiling is a typical “other space.” The same wiring methods can be used in these “other spaces” as used in fabricated ducts, with the addition of Armored Cable (Type AC cable) and Metal-Clad Cable (Type MC cable) of the interlocked style, and totally enclosed, non-ventilated, insulated busway without provisions for plug-in connections. Factory-assembled multiconductor control or power cable specifically listed for use in these other spaces can be used. Surface metal raceways or metal wireways can also be used. In an “other space for environmental air,” liquidtight flexible metal conduit is permitted in single lengths of 6 feet or less.

In summary, it is important to know that while Interlocked Metal-Clad Cable, without any PVC jacketing, is not technically “Plenum” rated it is perfectly acceptable to be located in an environmental air space, such as the space above a suspended to dropped ceiling in accordance with National Electrical Code section 300.22(C).

Attached is an image that clarifies the spaces mentioned in this article. Location “A” depicts the Environmental Air Space (plenum) where the circulation system is pulling air from the room into the hollow space above a ceiling. The “air” is from the environment. Location “B” is the enclosed portion of the system that is considered the “plenum” space. Location “A” is covered by 300.22(C) and “B” is covered by 300.22(B) which aligns itself with ducts that are fabricated for environmental air.

Paul W Abernathy, CMI, CMECP

National Electrical Code, NFPA or NEC are Registered Trademarks of the National Fire Protection Association and are used in this article for educational purposes only.

Friday, December 30, 2016

Electrical Conductors, Electrical Wires and Electrical Cables - Explained

Electrical Conductors, Electrical Wires and Electrical Cables

 Over the past 30 years the term Conductors, Wires and Cables have been intertwined in a world of misunderstanding and potential misapplication. This article will attempt to bring clarity to these terms for everyday use in the electrical industry from a manufacturers perspective.

The best way to begin to understand the differences is to attempt to define them in my own words.

Electrical Cable(s) - Electrical cable(s) are an assembly consisting of one or more conductors with their own insulations, individual covering(s), and protective jacketing.

Electrical Wire(s) - a thread or strand of copper or aluminum, typically manufactured from 5/16” or 3/8” solid copper or aluminum rods, then reduced down through a series of forming dies into specific standardized sizes and ultimately used as bare or insulated electrical conductors with thermoplastic, thermosetting or other listed insulating material along with additional coverings, where required by it’s associated UL Standard.

Electrical Conductor(s) - an electrical conductor, of the wire type, is an electrical wire, available in solid or stranded design, and is produced to allow the flow of electrical current in one or more directions. A copper or aluminum bare or insulated electrical wire is a common electrical conductor of the wire type.

While these definitions are my interpretation of their meanings, it is also important to understand that not all electrical conductors are actually of the wire type. There are other electrical conductors in the electrical industry that are not of the wire type yet considered to be electrical conductors. We are only focusing this article on the wire type of electrical conductor.

When you examine the term electrical cable, the reader has to understand that cables can be of the single or multiple electrical wire type. The single electrical wires of a cable would have the same basic electrical cable elements as a multi-conductor cable, having a core electrical wire, typically with an insulating material prescribed by the governing standard to which it is being constructed and used as an electrical conductor, which is ultimately protected by an outer jacket or sheathing, where required by the UL Standard. The combination of these elements creates a single cable. In a multi-conductor cable you have multiple electrical wires, grouped or cabled together to form the core, which is ultimately jacketed in a protective sheathing to form a completed, and UL listed cable assembly.

It is this author’s opinion that simply twisting or cabling electrical wires together doesn’t automatically create a cable assembly. Those would simply be electrical wires, being used as electrical conductors, which are simply twisted or cabled together to form the core design of an electrical cable assembly. All cable assemblies have to be listed by a Nationally Recognized Testing Laboratory (NRTL) and constructed in accordance with Underwriters Laboratory (UL) exacting standards. It is also important to understand that there are indeed cable assemblies that do not have an protective jacket yet are still UL listed for a specific application, for example, Deep Well Submersible Pump Cable which can come with or without a protective jacket or sheathing as long as it is listed and labeled for the specific application of use in accordance with UL. Simply twisting or cabling individual electrical wires would not by itself constitute a cable assembly unless it has been evaluated, listed and labeled as such.

 Now in support of this article we only need to examine the National Electrical Code [NEC] to see how the various terms are used. In Article 310, the code is clearly referencing conductors. The familiar conductor allowable ampacities, adjustments and corrections tables found in section 310.15 reference conductors and their association with how they are to be used. Chapter 3 of the code references the various acceptable wiring methods, which all of the cables associated are to be of the listed type.

The transition from a manufactured electrical wire to what the NEC considered an electrical conductor, of the wire type, is theoretically being transformed within Article 310 of the NEC. The articles within chapter 3 begin to take those electrical conductors and utilize them into listed cable assembly types for use in the building wiring industry.

Now, let’s look at the UL White Book, which I affectionately call the extended edition of the National Electrical Code. In examining the section titled “ Wire and Cable Markings”, the reader will quickly get an idea of what UL considered a wire versus a cable. Clearly electrical wires can be constructed into a cable assembly for ultimate listing and labeling but the difference is quite evident. In some cases like Type USE-2 cable, you indeed have individual electrical wires, now transformed into electrical conductors of the wire type, with or without a protective jacket or sheathing that have indeed been evaluated for use as a cable in or itself. However, what is clear is that you simply do not call an XHHW-2 or a THHN/THWN-2 a cable when it is indeed within the eyes of UL and the NEC an electrical conductor of the wire type, which was transformed from being manufactured as simply an electrical wire.

Lastly, while I do not put a lot of assurance in “Google™” searches, and the results below confirm this position, I did a search on the following phrase “ What is the difference between a wire and a cable” and the search results are interesting, which as expected I do not 100% agree with:
 “A wire is a single conductor (material most commonly being copper or aluminum) while cable is two or more insulated wires wrapped in one jacket.”

As we have seen it doesn’t technically take two or more insulated electrical wires or electrical conductors of the wire type to be considered a cable, and clearly in many cases the protective jacket or sheathing is optional. What is clear is that all cables have to be listed and labeled for their specific use and taking individually UL Listed electrical wires or electrical conductors of the wire type and twisting them together do not guarantee they are to be considered a cable assembly.

As opinions will vary, the goal here was to attempt to simplify the basic understanding of the differences in electrical conductors, electrical wires and electrical cables and I hope we have succeeded in that effort.

Update: Clearly the 2017 National Electrical Code and Code Making Panel 8 agreed with my interpretation as evident in this Chapter 9, Table 1, Note 9 change in the 2017 NEC :

"Assemblies of single insulated conductors without an overall covering shall not be considered a cable when determining conduit or tubing fill area. The conduit or tubing fill for the assemblies shall be calculated based upon the individual conductors"

Paul W Abernathy, CMI, CPI
CEO & President of Electrical Code Academy, Inc.

 References: 2014 UL White Book - Guide Information For Electrical Equipment
                       2014 National Electrical Code (NEC-NFPA70)

 NEC and the National Electrical Code are registered trademarks of the National Fire Protection Association and in no way endorse my opinions within this article.

UL is a registered trademark of Underwriters Laboratory and in no way endorse my opinions within this article.

Sizing Circular Raceways for Multiconductor Cables - Explained!

From time to time we get asked how to size a raceway where SE-R Cable is to be installed and how do we calculate the raceway fill requirements found in Chapter 9, Table 1 of the 2017 NEC*.

Determining the raceway fill for a complete raceway system (not for protection from physical damage) where Type SE-R Cable is to be installed is a simple calculation that often leaves electricians, engineers and inspectors confused. Again, keep in mind that this doesn't apply to short sections of raceway being used as physical protection for the SE-R Cable as denoted in Chapter 9, Table 1, Note 2 of the 2017 NEC.

All cable manufactures provide the diameter of their cables. This is usually found on their product information cut sheets. We will use our 4/0-4/0-4/0-2/0 AL SE-R from Encore Wire as an example for this article.

Since we are working with a cable assembly you need to determine what percentage of raceway fill the installer has to observe. Based on Chapter 9, Table 1, Note 9; a multiconductor cable of two or more conductors shall be treated as a single conductor for calculating percentage conduit fill area. Table 1 of Chapter 9 states that a single conductor (1) is to have a 53% maximum cross sectional area fill.

Once the fill percentage is established the user will draw their attention to the cable itself. In our published specifications reflects the diameter (straight across the cable from high point to high point) as 1.425 in. Based on the guidance provided in Chapter 9, Table 1, Note 9 of the 2017 NEC, the installer is going to use that diameter to perform a calculation nested within a normal mathematical formula.

Now, since we are looking for the area then we need to use that aforementioned formula to convert the diameter to an area. That formula can be done a few different ways. (𝝿/4) x D² is the base formula, in our case (𝝿/4) x 1.425² , which we added the diameter in place of the "D" in the formula. In complete value our formula is expressed as the following : 3.1415926536 ÷ 4 x 2.030625 = 1.5948491456 or simplified to 1.5948 which is now the approximate area for use with Chapter 9, Table 4.

As with any other raceway fill calculations, Table 4 comes into play. Once you have selected the raceway method you are installing, scroll over to the 53% fill column and find a raceway that will handle the 1.5948 in², which if the raceway was PVC Schedule 40 would result in a trade size 2 conduit. Again the benefit here is that the cable is considered a single conductor and can utilize the fill all the way to 53%.

Lastly, I also get questions on how to do this same calculation on a Type SE-U, NM-B, or UF-B cable and the calculation is just as simple. Chapter 9, Table 1, Note 9 also addresses "Elliptical" cross sectional areas as well. The NEC directs you to use the major diameter of the ellipse as a circle diameter just the same way we did for the previous Type SE-R example. The values for these types of cables are also found on the manufacturers product cut sheets or can be determined using a caliper tool where needed.

While this is not very complicated, it does generate many questions over the years on how to do the calculation, the hope is that this article will help eliminate the confusion on how to determine raceway fill for cables installed in circular raceways.

By Paul W Abernathy, CMI

CEO & President of Electrical Code Academy, Inc.

All Rights Reserved- Copyright 2016-2017

*NEC is a Registered trademark of the NFPA, National Fire Protection Association. We are not associated nor affiliated with NFPA.

Entrance to and Egress from Working Space - Single Entrance Option 110.26(C)(2)(a)

Greetings Mr. Design Engineer,

Thank you for submitting your question with regards to the proper application of section 110.26(C)(2)(a) as it pertains to establishing a compliant and safe single entrance to and egress from large electrical equipment rated 1200 amps or more and over 6 feet wide that contain overcurrent devices, or control devices, or switching devices.

The general rule in section 110.26(C)(2) is that with respect to the aforementioned electrical equipment, one properly sized (24” or wider by 6.5’ or higher) entrance to and egress from opening at each end of the large electrical equipment. When this is not possible then the installer/designer has two options to the general rule. We will focus on option 110.26(C)(2)(a) in this part of the series.

110.26(C)(2)(a) - Unobstructed egress. For example, switchgear located in a room that offers proper working space clearances per section 110.26(A)(1) and provides no additional ability to maneuver around the working clearance space in the event of an electrical accident or hazardous occurrence where no adequate opening at each end of the equipment per the general rule is provided. The designer has created a serious unsafe condition to the future electrical worker.

Assuming you have the proper working space clearance in front of the electrical equipment and then another few feet to freely maneuver around the potential hazard without having to egress through the actual working space clearance then one unobstructed entrance to and egress from the working space may be acceptable. However, it is vital to understand that when using this option you can’t use the working space clearance as the egress path because it has the potential to be an obstruction in a potentially hazardous event, such as an electrical fire that could effectively block an electrical worker, inspector, engineer or visitor to one side of the electrical equipment.

The reason the general rule requires properly sized entrances to and egress from both sides of the working space and electrical equipment as described earlier is to provide the electrical worker or other unfortunate individual two direct paths out of the potentially hazardous event area. The allowance for one entrance to and egress from the working space is when you can clearly step back out of the working space and then proceed unobstructed to the properly sized opening, while removing the unnecessary and potentially dangerous movement through the working space.

Need more evidence? Notice the second option 110.26(C)(2)(b), known as the double working clearance option, you double the working space clearance as expressed in 110.26(A)(1), you maintain no less than the prescribed working space clearance as defined in section 110.26(A)(1) from the nearest edge of the electrical equipment to the entrance. This double the working clearance and minimum clearance to the entrance from the electrical equipment provides the ability to step back into the “double” working space zone provided and effectively egress out the opening without having to traverse through the working space clearances as defined in section 110.26(A)(1).

In closing, It is my opinion that those who accept an installation that could place workers in danger and who knowingly permit improper application of the NEC rules may be found negligent in the event someone is trapped and ultimately harmed or killed in an electrical accident.

Best regards,

Paul W. Abernathy, CMI, CPI
Electrical Code Academy, Inc.