Heat tracing is a vital technology used to prevent freezing and maintain the flow of fluids in pipelines, vessels, and other industrial applications. While heat trace systems provide numerous benefits, they also present potential hazards, particularly regarding electrical safety. Ground faults can occur in these systems and, if left unaddressed, can lead to severe accidents, damage, and costly downtime. To mitigate these risks, ground fault equipment protection (GFEP) is essential for heat trace applications.
Heat trace systems are used in various industries, including oil and gas, chemical processing, food and beverage, and water treatment. They are used to prevent freezing, maintain process temperatures, and ensure the smooth operation of critical processes. These systems consist of heating cables or tapes installed along pipes, tanks, and other equipment to provide controlled and consistent heat.
A ground fault is an unintentional electrical connection between an energized conductor and a grounded surface, such as a metal pipe or equipment enclosure. Ground faults can arise from insulation failure, damaged cables, improper installation, or environmental factors. Heat trace applications in North America are typically solidly grounded systems. An electrical system is said to be solidly grounded when the neutral line is directly connected to ground potential. This type of electrical system allows line-to-neutral current and makes ground faults relatively more straightforward to detect than ungrounded systems. Unfortunately, when a ground fault occurs in a solidly grounded system, it tends to be a very high current. Therefore the system must trip rapidly to prevent dangerous shock risk or fire.
Ground fault equipment protection is essential for heat trace applications for several reasons:
Because heat trace systems are typically solidly grounded, the primary Bender products used to establish ground fault equipment protection are Residual Current Monitors (RCMs) and Current Transformers (CTs). Typically, Bender recommends either an RCMS460, RCM410, or RCM420 depending on the application. To detect ground faults with an RCM device, all conductors of the outgoing circuit to be monitored (except the ground conductor) are routed through a measuring CT. In a fault-free system, the sum of all currents equals zero so that no voltage is induced in the CT. If a fault current (IΔ) flows via ground (or other paths) the difference in current generates a voltage on the CT that is detected by the RCM. The output signal from an RCM can then be fed into a breaker or contactor to the circuit in the event of a ground fault.
Though many small heat trace applications can be protected with only a GFCI-breaker or similar device, a system utilizing an RCM, CT, and shunt-trip breaker/contactor allows more flexibility, such as compatibility with higher load currents and voltages. With Bender technology, users also receive EoL device failure notifications thanks to our devices conducting automatic self-testing to indicate if they are no longer functional.
The RCM example below can be connected to shunt-rip breakers or a contactor to enable tripping when a ground fault is detected or can be used for alarm purposes only in applications that are granted. An exception to this is under NEC 427.22 due to critical loads that cannot be safely shut down even in the case of a ground fault.