The Basics of Stray Current Control

Reducing or preventing corrosion is a main concern in electrical systems. When DC voltages exist in applications such as railway traction, solar or battery power systems, corrosion can cause major issues in terms of grounding system integrity and effectiveness, or even environmental issues with unintended leakage from underground pipelines.

In this post, we investigate how stray currents come about and discuss ways to design your electrical systems for managing stray currents, or protect it from an unforeseen source of stray currents.

What Are Stray Currents?

stray current refers to the current flowing through paths other than the intended electrical circuit. This is present in DC power systems such as shown in the diagram below showing a railway application. In this example, the direct current comes from the power supply via an overhead circuit to power the train and the return current flowing back to the power supply (source) via the train running rails. Within the example, a potential parallel path back to the source is shown as a nearby metallic pipeline. Stray current is the portion of the return current that finds its way back to the source via other means such as the pipeline. Other mediums could be structural steel, hand-railings or other grounded bodies.

StrayCurrentDiagram

The above example is specific to railway DC applications; however, stray currents can present in a range of applications from photovoltaic solar, DC, battery power or pipeline systems that may share a service corridor with another service. All metallic structures buried or contained within a medium, e.g. concrete, are susceptible to stray current corrosion. Stray current corrosion can also occur around AC power systems, where long term AC interference coupling with metallic structure, the intensity however will depend on the level of DC polarization or magnitude of the interference. Very high levels of interference are required in these cases and the problems experienced in practical applications are far less than that in the case of DC power systems.

How Does Stray Current Lead To Corrosion?

Corrosion from stray currents occurs at the point of discharge of the current from a conductor, i.e. the point where the current leaves a conductor and transitions to another medium. For example, the diagram below shows a potential corrosion point within the circuit caused by stray currents. Corrosion can also occur in this example at points where the stray current leaves the running rail return path.

At the point of entry of the current and along the length of the conductive path that carries the stray current, there is no corrosion resulting. At these points of entry, stray current provides a certain degree of cathodic protection to the metallic structure.

Corrosion resulting from stray current is an electrolysis process. Within the electrolysis process, the stray current alone drives metal atoms into an electrolyte as water-soluble ions. The extent of damage or loss of metal is directly proportional to the magnitude of stray current leaving the conductor at the point of discharge. Stray current corrosion tends to be localized at locations where the stray current leaves the metal structure and enters the electrolyte, e.g. soil/concrete/water.

StrayCurrentCorrosionDiagram

How To Protect Against Corrosion From Stray Currents?

Protection can be achieved against the corrosive effects of stray current by either negating the effects of the stray current by eliminating the stray current or by collecting the stray current via know paths. This is also referred to as stray current control.

By considering the potential leakage points of current from the intended electrical circuit or increasing the isolation of the circuit from the surrounding structures or even reducing the resistance of the return path circuit, effective protection against corrosion can be achieved. However, there may be applications where isolation is not possible. In these cases, a collection or shielding design can be introduced to collect any stray currents through a known pathway and return them in a control way back to the source.

In cases where the stray current cannot be controlled through isolation or dedicated collection systems, for example when the problem is discovered post construction, cathodic protection systems can be installed that impress an offsetting current into the structure adversely effected by the corrosion that may negate the effects of the stray currents on the structure to be protected.

Being aware of potential stray current parallel paths or sources is the most important thing to control stray current. Eliminating them as early as possible in the project stages is preferred, while other solutions exist to mitigate the effects of corrosion on a system once discovered.

In two weeks, read our next blog on the 3 Design Practices to Achieve Stray Current Control, which walks through examples of stray current collection system installations.

Reference: Earthing, Bonding and Stray Current Mitigation – Principles, Steve Case, IEEE SEM Journal 2005

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