Electrical energy is critical to modern industries but poses significant risks, including electrical shocks, burns, arc flashes, fires, and catastrophic equipment failures. Industries must also manage unique risks associated with portable battery-powered equipment, overhead powerlines, and underground or buried electrical hazards.
This article explores the key considerations, potential incidents, and effective management of electrical energy as a critical risk. By understanding these hazards and implementing robust controls, organisations can minimise the likelihood and impact of electrical incidents.
Industries and Common Electrical Energy Use
Electrical energy risks arise across various industries and contexts. Below are key sectors and their specific challenges:
Construction and Infrastructure
Temporary wiring, site installations, and exposed circuits.
Operating machinery near overhead powerlines or buried cables.
Mining and Resources
High-voltage systems and portable equipment in underground operations.
Use of battery-powered tools and vehicles in confined spaces.
Utilities and Public Works
High-voltage transmission lines, substations, and maintenance activities.
Underground cabling during urban excavation or maintenance projects.
Manufacturing and Warehousing
Fixed machinery, robotic systems, and conveyor belts powered by electricity.
Battery-operated forklifts and mobile equipment.
Agriculture
Electrical hazards from irrigation pumps, generators, and fencing.
Use of batteries in mobile equipment like tractors and drones.
Healthcare
Critical reliance on electricity for life-support systems and portable diagnostic tools.
Emergency backup systems reliant on large-scale batteries
Potential Incidents and Scenarios
Electrical energy incidents can cause injuries, fatalities, fires, equipment damage, and production stoppages. Understanding common scenarios is essential for developing targeted controls.
Contact with Live Electrical Systems
Accidental contact with exposed wires or equipment.
Improper de-energisation during maintenance.
Battery-Related Hazards
Battery overheating, leaking, or short-circuiting, leading to fires or toxic exposures.
Improper storage or disposal causing chemical burns or environmental damage.
Overhead Electrical Hazards
Machinery or vehicles contacting overhead powerlines during operations.
Cranes, elevated work platforms (EWPs), or drilling rigs in proximity to live lines.
Underground or Buried Electrical Hazards
Striking underground cables during excavation or trenching.
Equipment operating on unstable or poorly mapped worksites.
Arc Flash or Explosions
High-energy electrical discharges causing burns and severe injuries.
Sparks igniting flammable substances near electrical systems.
Electric Shock
Direct or indirect contact with live equipment causing injuries or fatalities.
Increased risks in wet or conductive environments.
Fire Hazards
Overloaded circuits, faulty batteries, or equipment failures leading to electrical fires.
Fires caused by damaged underground or overhead cabling.
Common Dynamics Contributing to Incidents
Inadequately managed electrical infrastructure.
Poor storage and/or usage of electrical appliances.
Poor emergency response planning or equipment readiness.
Establishing Your Context for Electrical Energy Risk Management
Before implementing controls, define the scope of your electrical risk management program. Consider the following:
Scope of Activities:
Will you address all electrical systems or prioritise high-risk activities like battery storage, live-line work, or excavation?
Exposure Areas:
Identify workplaces with significant overhead or buried electrical risks.
Include areas reliant on battery-powered tools or portable systems.
Stakeholder Involvement:
Engage key stakeholders such as electricians, engineers, supervisors, and equipment operators.
Clearly defining your context ensures that your risk management efforts are focused and effective.
Identifying Relevant Scenarios
Once the context is clear, identify the relevant electrical scenarios in your operations.
High-Risk Activities
Working near live overhead or buried cables during excavation or lifting operations.
Maintenance or troubleshooting of high-voltage systems or battery arrays.
High-Exposure Environments
Confined spaces with battery-powered tools or low ventilation.
Construction sites with temporary electrical setups or hazardous terrain.
Equipment Types
Portable battery systems, forklifts, or cranes with electrical components.
High-voltage substations and underground cabling systems.
Constructing Your Critical Risk Bowtie Analysis
A Critical Risk Bowtie Analysis is a powerful tool for managing confined space risks. It maps the pathways leading to incidents and identifies controls that can prevent or mitigate them.
Step 1: Define Your Unwanted Event - Centre of Bowtie
The first step is to identify your unwanted event, which is the critical scenario or grouping you aim to manage, such as electric shock or arc flash incident. This event represents the central focus of your analysis—the point where risk must be prevented or mitigated. Select an unwanted event that could lead to the highest consequence outcomes in your context.
For example, you may choose to prioritise high-risk scenarios first and address lower-priority areas in subsequent analyses.
Step 2: Identify Causes (Threats) - Left-Hand-Side of Bowtie
Once your unwanted event is established, the next step is to identify the causes or threats that could lead to it.
These causes must be likely and direct pathways to the event.
Avoid being too broad or generic, as this can dilute the analysis and lead to ineffective control identification.
Examples include:
Improper equipment isolation.
Exposed wires.
Faulty batteries.
By focusing on specific causes, you ensure that your controls are tailored and relevant to managing the risk.
Step 3: Identify Consequences (Impacts) - Right-Hand-Side of Bowtie
Next, identify the consequences or impacts that could result from the unwanted event occurring.
Consequences must be direct outcomes of the event.
These help you understand what’s at stake and guide the development of appropriate mitigating measures.
Examples include:
Worker arc flash injury.
Worker fatality.
Fire.
Like causes, keeping consequences specific ensures the analysis remains focused and actionable.
Step 4: Map Preventing and Mitigating Controls
Once you have identified causes and consequences, it’s time to map out controls. Controls are the measures implemented to either prevent the unwanted event from occurring or reduce its impact if it does. Start with identifying what controls you already have in place managing the critical risk, then you can start to identify gaps and opportunities to strengthen your causal pathway with proposed or new controls. Controls are acts, objects or technical systems. Try to call out the actual control, not the document that manages the control.
Preventing Controls
These controls address the causes (threats) on the left side of the bowtie.
Their purpose is to stop the unwanted event from happening.
Think of them as barriers that block or interrupt the progression from a cause to the unwanted event.
Examples include:
Electrical Isolation: Lockout-tagout systems to de-energise circuits before work.
Battery Storage: Properly labelled, ventilated storage areas with spill containment.
Mapping Overhead and Underground Hazards: Use of ground-penetrating radar or GIS systems to locate hazards.
Mitigating Controls
These controls address the consequences (impacts) on the right side of the bowtie.
Their purpose is to reduce the severity or extent of the impacts if the unwanted event occurs.
They act as safety nets that limit harm, damage, or loss.
Examples include:
Arc-Rated PPE: Insulated gloves, face shields, and arc-resistant clothing.
Emergency Fire Suppression: Systems for electrical fires or battery overheating.
Emergency Response Kits: First-aid kits and defibrillators for electrical injuries.
By clearly distinguishing preventing and mitigating controls, the bowtie ensures you’re addressing both the likelihood and the consequences of the event.
Why Focus and Specificity Matter
The success of a bowtie analysis hinges on its ability to identify specific controls that effectively manage risks. If the causes or consequences are too broad, you risk overlooking critical controls or diluting their effectiveness. A focused analysis ensures that every identified control is targeted, actionable, and essential.
By following these steps, you can construct a comprehensive bowtie analysis that visualises your critical risks and the pathways to managing them.
Identifying Critical Controls
Critical controls are the cornerstone of managing risks in a bowtie analysis. These are the controls that, if absent, ineffective, or failed, would have a significant impact on the likelihood of an unwanted event occurring or on the severity of its consequences. Proper identification and selection of critical controls ensure that resources are focused on the most important barriers to risk.
Preventing Critical Controls
Preventing critical controls are focused on the causal pathways leading to the unwanted event. These controls act as barriers to stop the event from occurring.
What to Ask:
Would the absence or failure of this control significantly increase the likelihood of the unwanted event?
Is this control essential to interrupting the causal pathway?
By identifying and implementing preventing critical controls, you can drastically reduce the probability of the unwanted event occurring.
Mitigating Critical Controls
Mitigating critical controls are focused on the consequences of the unwanted event. These controls do not stop the event from occurring but instead limit its severity or extent.
What to Ask:
Would the absence or failure of this control result in the highest potential consequence?
Is this control critical to reducing harm, damage, or loss if the unwanted event occurs?
Mitigating critical controls ensure that even if the event occurs, the outcomes are managed to minimise harm.
Key Considerations for Identifying Critical Controls
Critical controls must be effective, measurable, and reliable to ensure they perform as intended.
Avoid overloading the analysis with non-critical controls. Focus only on those that significantly influence the risk pathways or outcomes.
By selecting critical controls with this structured approach, you create a robust system that prioritises the most impactful barriers to risk.
Critical Control Management
Critical control management is an essential component of effective risk management. It ensures that the most important controls in your system are clearly understood, properly implemented, and rigorously maintained to prevent or mitigate high-consequence events. This process involves understanding each critical control’s requirements, verifying their effectiveness, and managing their performance over time.
Critical Control Performance Requirements
To effectively manage critical controls, it is crucial to understand their performance requirements. This involves developing a Critical Control Performance Standard that clearly defines the expectations and parameters for each control. The performance standard should include the following key elements:
Objectives of the Critical Control
Define the purpose of each control, such as maintaining safe distances to live electrical equipment.
Performance Requirements
Define how the control must perform to meet its objectives. This includes specifying measurable criteria, such as equipment shutting down immediately when overloading is detected.
Critical Operating Parameters
Identify operational thresholds or conditions under which the control must remain effective, such as electrical equipment must remain isolated for the duration of the work.
Failure Modes
Outline potential mechanisms of failure and how they might occur (e.g., wear and tear, human error, environmental factors, RCD malfunctions).
Training Requirements
Specify the knowledge and skills required for personnel to operate, inspect, and maintain the critical control effectively.
Maintenance and Inspection Requirements
Detail the frequency and type of maintenance activities, as well as inspection protocols to ensure ongoing functionality.
Critical Control Verification (CCV) Process
The Critical Control Verification (CCV) process is vital for ensuring that critical controls are implemented, effective, and not at risk of failure. This process typically involves three primary activities:
Verifying Critical Controls Are in Place
In-Field Observations: Confirm that critical controls have been physically implemented in the workplace. For example, proper use of work permits, PPE is being worn, or procedures are present and accessible.
Verifying Critical Controls Are Effective
In-Field Testing: Test the functionality of critical controls to ensure they perform as intended. For example, attempt to re-energise electrical equipment (if safe to do so).
Verifying Critical Controls Are Not at Risk of Failure
Maintenance Programs: Ensure regular servicing, repairs, and inspections are conducted to prevent degradation or failure.
Audits and Certifications: Use independent or internal audits to confirm compliance with performance standards and identify potential risks.
Detecting Failure Mechanisms: Monitor and address early signs of failure, such as wear and tear, system alerts, or operational deviations.
Defining Verification Frequency
The frequency of verification activities should be based on the level of exposure and the number of areas where the critical control is implemented. Consider the following factors:
High-Exposure Areas
For controls in high-risk or high-frequency areas (e.g., environments with high voltage electrical apparatus that requires frequent repairs), verification should occur more frequently to account for the increased likelihood of failure or incident.
Multiple Implementation Sites
When a control is implemented across numerous locations (e.g., operations with multiple substations, transformers), verification activities should be scaled to ensure all instances are regularly checked.
Risk-Based Scheduling
Use the severity of potential consequences and historical performance data to determine appropriate intervals for verification (e.g., daily, weekly, or monthly checks).
Why Critical Control Management Matters
By systematically managing critical controls, organisations can ensure that these essential barriers remain functional, reliable, and aligned with their intended objectives. Performance standards provide a clear understanding of how controls should operate, while verification processes offer confidence that controls are effective and ready to respond when needed.
This structured approach ensures that risks are not only managed but also proactively mitigated, contributing to a safer and more resilient workplace.
Conclusion: Managing Electrical Energy as a Critical Risk
Electrical energy risks span a wide range of scenarios, from live-line hazards to battery fires and underground cable strikes. By constructing a bowtie analysis, identifying critical controls, and implementing robust management processes, organisations can significantly reduce risks.
To support your efforts, we offer the Electrical Energy Critical Risk Package, tailored to your industry and specific electrical challenges.
Who We Work With
We have extensive experience developing successful critical risk management and critical control programs for a diverse range of clients, including:
Glencore
BHP
Ampol Australia
Local councils
Leading construction companies
Manufacturing companies
NDIS providers
Charities and not-for-profits
Our expertise spans industries and sectors, allowing us to tailor solutions to meet the unique challenges faced by our clients. Let us bring this experience to your organisation and help you achieve effective and sustainable risk management outcomes.
What’s Included:
Tailored Approach: Customised to your industry and electrical hazards.
Comprehensive Bowtie Analysis: A detailed analysis of causes, consequences, and controls.
Critical Control Identification and Selection: Structured tools to identify and prioritise critical controls.
Critical Control Performance Standard Document Suite: Define objectives, performance requirements, and training needs for each critical control.
Critical Control Verification Document Suite: Ensure controls are effective and not at risk of failure through observation and testing tools.
Consultation and Implementation Guide: Step-by-step guidance to integrate the package effectively.
Worker Toolbox Talk: Equip your team with the knowledge to manage electrical risks.
Tailored to a Single Bowtie Analysis
This package is designed for a single bowtie analysis, focusing on a well-defined grouping of scenarios that form an unwanted event. Selecting an appropriate grouping ensures the analysis is precise, actionable, and effective in managing your critical risks.
By leveraging this comprehensive package, you can streamline your risk management process, ensuring critical controls are in place, effective, and verifiable. Click below to take the first step in managing your confined space critical risks confidently and effectively.
You will be asked in the checkout to provide information on your industry and the activities you'd like included in the electrical energy critical risk package.
Further customisations will be required including context and scenarios. This package will be delivered via email within 5 business days.
Principal Hazard Management Plan (PHMP) Confined Space
The Principal Hazard Management Plan (PHMP) is a vital document required by many industries to address high-consequence risks effectively. This add-on complements our Critical Risk Packages by providing a comprehensive framework tailored to your specific industry and operations.
What Is a Principal Hazard Management Plan (PHMP)?
A PHMP is a high-level strategic document that:
Identifies specific principal hazards in your operations (e.g., electrical energy, working at heights, confined spaces, or mobile equipment interactions).
Outlines your organisation's approach to managing these hazards, ensuring compliance with legislative and regulatory requirements.
Provides a clear structure for hazard assessment, risk controls, and ongoing monitoring.
What’s Included in the PHMP Add-On?
When you add the PHMP to your Critical Risk Package, you’ll receive:
Tailored Principal Hazard Management Plan:
A detailed plan aligned with your industry and operational requirements.
Integration of specific risks and controls identified in your Critical Risk Package.
Hazard Identification and Risk Assessment:
Comprehensive identification of principal hazards and associated risks.
Strategies to mitigate risks effectively and sustainably.
Compliance Framework:
Alignment with relevant industry legislation, standards, and codes of practice.
Monitoring and Review Framework:
Procedures for continuous improvement, audits, and periodic reviews.
Actionable Strategies:
Specific control measures, implementation steps, and roles/responsibilities.
Why Add a PHMP to Your Package?
Regulatory Compliance: Ensure your organisation meets all legislative requirements for managing principal hazards.
Customised Solutions: Receive a plan tailored to your operations, ensuring relevance and practicality.
Enhanced Risk Management: Build a robust framework to manage high-consequence risks effectively.
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