Getting Serious About Workplace Electrical Safety – Electric Shock Edition from iGard

April 24, 2023

Keeping employees safe at work has to be responsibility number one for a company. What is the rationale for being profitable if unsafe, or delivering product quickly to the customer if the workplace is unsafe and so everyone agrees that workplace safety is a priority but then we need to ask why are the incident rates of electrical injuries and in some case fatalities not reducing year over year, if keeping employees safe is a priority? 

From 2011 to 2020 the rate on non-fatal injuries due to exposure to electricity remains relatively unchanged despite extensive campaigns around electrical safety and the use of PPE.

The table to the right is for all establishments and not specifically manufacturing establishments which tend to have the second highest incident rates after construction.

From 2003 – 2018 there were 1,910 electrical burn injuries in manufacturing establishments and the typical cause is arc flash incidents. These receive a lot of press coverage due to the devastating nature of an arc flash and the destructive impact. Yet, during the same time period there were 4,010 electric shock incidents in manufacturing facilities and while 50% of victims only missed 1-2 days of work, more than 25% of victims missed 3 weeks or longer due to their injuries. 

Perhaps the greater concern is that there was an increase from 2019 to 2020 in the number of incidents that were related to installation, maintenance and repair of equipment and that while the expectation would be that these were inexperienced personnel, statistical data indicates that 33% of the workers impacted by an electrical hazard had more than 1 year of experience and 32% had more than 5 years of experience. 

 One positive trend is the reduction in fatalities due to exposure to electricity from 166 in 2019 to 126 in 2020, although some of this is attributable to the covid-19 pandemic and a reduction in hours being worked at manufacturing facilities not considered essential. 

The question therefore is what can be done to ensure an electrically safe work condition and to reduce the number of fatal and non-fatal injuries each year. 

Electrically Safe Working Conditions

Electrically Safe Work Condition –  A state in which an electrical conductor or circuit part has been disconnected from energized parts, locked / tagged out in accordance with established standards, tested to verify the absence of voltage, and, if necessary, temporarily grounded for personnel protection. 

There are two references with respect to establishing an electrically safe work condition and the first is OSHA (Occupational Safety and Health Administration) and the second is National Standards. For the US this would be NFPA70E Standard for Electrical Safety in the Workplace, for Canada this would be CSA Z462 Workplace Electrical Safety and similar publications for other countries. 

OSHA 1910 Occupational Safety and Health Standards 1910.333 Selection and Use of Work Practices states the following: 

1910.333 a) Safety-related work practices shall be employed to prevent electric shock or other injuries resulting from either direct or indirect electrical contacts, when work is performed near or on equipment or circuits which are or may be energized. 

1910.333(b)(2)(iv)(B) A qualified person shall use test equipment to test the circuit elements and electrical parts of equipment to which employees will be exposed and shall verify that the circuit elements and equipment parts are de-energized. The test shall also determine if any energized condition exists as a result of inadvertently induced voltage or unrelated voltage back-feed even though specific parts of the circuit have been de-energized and presumed to be safe. 

Both NFPA 70E and CSA Z462 have undergone significant changes over the past 6 years as noted below. 

In 2015 edition the only prescribed option to verify an electrically safe work condition was to use a multi-meter and test the phase conductors or circuit paths directly. This requires opening the door to the electrical cabinet, after donning the appropriate safety equipment, and making direct contact. This approach involves risk from unintentional contact with possible current carrying conductors or from selecting a meter that is not adequately rated or set incorrectly. A study in 1995 indicated that 18.3% of facilities experienced a personnel injury when using hand held meters to conduct the test.

In 2018 NFPA 70E was updated and introduced the option to use an adequately rated permanently mounted electrical test device to be used to verify the absence of voltage and this led to the proliferation of companies using voltage indicators and test ports to conduct this important test. The rationale was simple, you conduct the test with the door closed and therefore reduce the risk of unintentional contact with current carrying conductors and the end result should be a substantial reduction in the fatal and non-fatal statistics.  

No such reduction in incidents rates occurred and the question needs to be asked why and one simple explanation may be that the products being used were not suited for the specific application. Reading zero volts at the end of a test port simply indicates that there is no voltage at the test port but does not guarantee that there is no voltage on the current carrying conductors.

What if a lead is missing or lose, what if the fuse between the test port and the current carrying conductor is blown, in each instance you would read zero on the meter inserted into the test port but the actual situation would remain dangerous due to voltage still being present. Perhaps qualified workers do not 100% trust the results from using a voltage test port and resort to opening the door to the electrical cabinet thereby putting themselves at risk. 

In 2021 NFPA 70E went through a further update and the term electrical test device was removed and replaced with absence of voltage tester with an informational note that an absence of voltage tester must meet the requirements of UL 1436.  According to UL 1436 an absence of voltage tester is defined as:- 

A permanently-mounted test device that is used to verify that a circuit is de-energized prior to opening an electrical enclosure that contains energized electrical conductors or circuit paths.  An AVT is provided with a test circuit with active indications to verify the absence of phase-to-phase and phase-to-ground voltage.

On the surface an absence of voltage tester does not appear to be different from a voltage indicator but there are significant differences and all related to the design, architecture and operational clauses contained with UL 1436. 

An absence of voltage tester undertakes all of the same tests as a qualified person would undertake using a multi-meter. That is all current carrying conductors and circuit parts are measured phase to phase and phase to ground to verify that there is an absence of voltage. The absence of voltage tester must also ensure via a supervisory circuit that it is functioning satisfactorily and that it conducts continuity checks to verify that all connections are secure and connected in the correct manner. 

The test sequence of the absence of voltage tester is visually represented below and the entire sequence is performed in around 10 seconds and all with the door to the electrical cabinet closed and personnel removed from the risk of unintentional contact. 

If the test is successful and there is less than 3 volts AC or DC present in the circuit then the absence of voltage tester will provide three (3) green lights for a period of five (5) seconds. This provides positive indication that the situation is safe and that you can open the door to the electrical panel. 

If the test is unsuccessful then the amber lights on the absence of voltage tester will remain illuminated as indication that an unsafe condition may still be present. The next logical step would be to retest the installation and wait a further 10 seconds as the cause could be residual voltage that has yet to fully dissipate. If the test comes back unsuccessful a second time, then the only option is to don PPE if needed, open the door and troubleshoot the situation. 

If using an absence of voltage tester is as simple as pressing a button and waiting ten (10) seconds, if it is safe and reliable then why are there so few installed already. The answer is twofold, misinformation and market inertia or distrust. 

Tackling Misinformation 

The addition of Exception No.1 in the 2018 edition of NFPA70E allowed for the use of a permanently mounted electrical test device to be used and with the market having accepted this approach the question is whether there really is a difference between a voltage test port and an absence of voltage tester and whether a voltage test port can be used to conduct an absence of voltage test? 

The major difference between a voltage test port and an absence of voltage tester are design, functionality and certification standards. A voltage test port (with our without voltage indication included) is a test device that is designed and tested to UL 61010 and the purpose is to measure voltage.  

An absence of voltage tester is designed and tested to UL 1436 and the purpose is to verify the absence of voltage, and UL contains multiple design and test clauses that a voltage test port does not comply with. 

There is also the small fact of OSHA’s interpretation – It was stated by OSHA Directorate of Enforcement Programs that: 

1910.333(b)(2)(iv)(B) generally does not permit testing a circuit at a point remote from the circuit elements and equipment parts to which the employee will be exposed. A voltage test port is remote from the circuit elements to which employees would be exposed and are therefore disallowed. 

If the OSHA provision in 1910.333(b)(2)(iv)(B) generally does not permit testing a circuit at a point remote from the circuit elements and equipment parts to which the employee will be exposed and this disallows permanently mounted test devices such as a voltage test port, then why would OSHA allow a UL approved absence of voltage tester to be used? 

Exception 1 to NFPA70E 120.5 Rule 7 states ““An adequately rated permanently mounted absence of voltage tester shall be permitted to be used to test for the absence of voltage of the conductors or circuit parts at the work location, provided it meets all of the following requirements:  

(1) It is permanently mounted and installed in accordance with the manufacturer’s instructions and tests the conductors and circuit parts at the point of work; 

The point of work is the very circuit elements to equipment parts to which the employee will be exposed and not a point remote from them. 

An absence of voltage tester includes a connectivity check each and every time it is used to ensure that all leads are connected at the point of work 

Tackling Market Inertia or Distrust

Change is difficult and changing from an approach of using a multi-meter and testing current carrying conductors directly to pressing a button relying on technology faces distrust from the unknown, is the absence of voltage tester safe to use; how do I know it is installed properly; are the results reliable? 

Is it Safe to Use an Absence of Voltage Tester?

An absence of voltage tester display unit is door mounted and connected to the control module via a communication cable so that no hazardous voltage is brought to the door. 

The absence of voltage tester is installed on the load side of a disconnect switch and there are no connections to the line side. 

How Do I Know that it is Installed Properly?

Two sensor leads are connected to each phase and two sensor leads are connected to ground. 

Before conducting the absence of voltage test, the supervisory circuit built into the tester verifies that the leads are connected by injecting a signal down each connection. 

During the absence of voltage test there are two separate continuity tests to ensure that all leads are connected. 

Are the Results Reliable? 

As noted earlier the absence of voltage tester will provide three (3) green lights to indicate that the test has been successful and that it is safe to proceed but how do we know that the three (3) green lights are not in error? To answer that, we look to UL 1436 and the following clauses: 

12.1.6 – The AVT visual indicator shall only illuminate green when all phase-to-phase and phase-to-ground voltages measure less than 3VAC or 3VDC. 
12.1.7 The AVT visual indicators shall not illuminate green unless the phase and ground leads are in direct contact with the circuit conductors being tested 
12.1.8 – The AVT visual indicator shall not illuminate green if a phase lead is connected to ground or the ground lead is connected to a phase conductor. 
12.1.9 12.1.9 The visual indicator shall not illuminate green unless the secondary power source is operational 
12.2.1 – The AVT shall comply with the Standard for Functional Safety IEC 61508 and achieve a SIL 3 rating. 

Functional Safety IEC 61508 and SIL 3 (safety integrity level 3) indicate the fail-safe nature of the product. To achieve SIL 3 the average failure in a hazardous condition, that is three (3) green lights incorrectly, has to be less than once in 10,000,000 hours of operation. That equates to one potential failure in more than 1,000 years. 

Changing from using a multi-meter to using an absence of voltage tester removes risk, is safer, is quicker but if hesitation still remains there is the option to mount both a voltage test port and an absence of voltage tester in a single enclosure.

Qualified personnel can use their trusted meter and the test port and then verify the results by waiting 10 seconds and using an approved absence of voltage tester.  

“Verifying De-energization – Time to Get Serious”

Webinar Presented by I-Gard Corporation

The presentation will provide an overview of relevant codes and standard including NFPA, CSA, UL1436 and OSHA 1910.333, the functional differences between an Absence of Voltage Tester that meets UL1436 and a Voltage Test Port that doesn’t, and why the Test Before Touch approach should be updated to using an approved Absence of Voltage Tester. There will also be a discussion on why users comfortable with utilizing a meter to verify de-energization should be comfortable and trust this new technology.

Related Articles

Network Infrastructure Featured Product Spotlight

PBUS 14 Panduit logo 400

This webinar presented by Beth Lessard and Keith Cordero will be highlighting three Panduit solutions that will optimize network equipment and cabling to ensure that your spaces are efficiently and properly managed to support ever-evolving business needs of today and beyond. Products that will be featured include PanZone TrueEdge Wall Mount Enclsoure, Cable Managers, and Adjustable Depth 4-Post Rack.

REGISTER HERE


Editor’s Pick: Featured Product News

Siemens: SIMOVAC Non-Arc-Resistant and SIMOVAC-AR Arc-Resistant Motor Controllers

The Siemens SIMOVAC medium-voltage non-arc-resistant and SIMOVAC-AR arc-resistant controllers have a modular design incorporating up to two 12SVC400 (400 A) controllers, housed in a freestanding sheet steel enclosure. Each controller is UL 347 class E2, equipped with three current-limiting fuses, a non-load-break isolating switch, and a fixed-mounted vacuum contactor (plug-in type optional for 12SVC400). The enclosure is designed for front access, allowing the equipment to be located with the rear of the equipment close to a non-combustible wall.

Read More


Sponsored Content
Electrify Your Enterprise

Power is vital to production, and well-designed control cabinets are key. Allied Electronics & Automation offers a comprehensive collection of control cabinet solutions including PLCs, HMIs, contactors, miniature circuit breakers, terminal block connectors, DIN-rail power supplies, pushbutton switches, motor starters, overloads, power relays, industrial Ethernet switches and AC drives engineered to keep your operations running safely, reliably and efficiently.

Learn more HERE.


Products for Panel Builders