Stored Energy

What is Stored Energy?

Types of Stored Energy with Common Examples:

Electrical Energy:

• • Example: The capacitors in a computer monitor that can hold a charge even after it's unplugged.

  • Example: Batteries in power tools or backup systems.

  • Example: Electrical circuits energized.

  • Example: Long runs of electrical cable, that can hold a residual charge.

  • Risks: Electric shock, burns, arcing.

  • Management: Discharge capacitors, disconnect batteries, lockout/tagout electrical circuits.

Mechanical Energy:

• • Example: The springs in a garage door opener.

  • Example: The flywheel on a machine that keeps spinning after power is off.

  • Example: A suspended load on a crane.

  • Risks: Crushing, impact, entanglement.

  • Management: Block moving parts, release tension, use locking pins.

Hydraulic Energy:

• • Example: The pressurized fluid in a car's hydraulic jack.

  • Example: The lines of a hydraulic press.

  • Risks: High-pressure fluid injection, crushing, impact.

  • Management: Relieve pressure, block hydraulic lines, lockout/tagout.

Pneumatic Energy:

• • Example: The compressed air in an air compressor tank.

  • Example: The air lines powering pneumatic tools.

  • Risks: High-pressure air release, impact, loud noise.

  • Management: Bleed air pressure, block pneumatic lines, lockout/tagout.

Thermal Energy: (hot or cold)

• • Example: Steam in a boiler.

  • Example: Molten metal in a foundry.

  • Example: Liquid nitrogen in a cryogenic container.

  • Risks: Burns, frostbite, steam explosions.

  • Management: Cool/warm materials, insulate surfaces, PPE.

Gravitational Energy:

• • Example: A heavy object suspended by a chain.

  • Example: A raised platform or work surface.

  • Risks: Crushing injuries from falling objects.

  • Management: Block or restrain objects, lower them to the lowest level possible.

Chemical Energy:

• • Example: Car batteries. (full of sulfuric acid)

  • Example: Chemical vats used in manufacturing.

  • Risks: Chemical burns, explosions, toxic fumes.

  • Management: Neutralize chemicals, PPE.

Common Ways to Manage Stored Energy Safely:

• Lockout/Tagout (LOTO): Using locks and tags to prevent equipment from being accidentally turned on.

• Energy Isolation: Physically disconnecting power sources.

• Energy Dissipation: Releasing stored energy.

• Blocking and Restraining: Using physical blocks to prevent movement.

• Bleeding and Venting: Releasing pressure from systems.

• Thermal Stabilization: Allowing temperatures to normalize.

• Verification: Checking that energy is truly gone.

• Training: Learning how to handle each type of energy safely.

• PPE: Wearing the right protective gear.

1. Identify and Isolate All Energy Sources:

Determine all potential energy sources: This includes not only the main power source but also any backup power supplies, capacitors, or other stored energy sources.

Locate all energy-isolating devices: These are devices that physically disconnect the circuit, such as circuit breakers, disconnect switches, or fused disconnects.  

De-energize the entire circuit: Turn off the circuit using the energy-isolating devices.

2. Apply Lockout Devices:

Attach lockout devices: Place locks on all energy-isolating devices in the "off" or "disconnected" position.  

Use appropriate lockout hardware: Use locks specifically designed for lockout/tagout purposes.

Each authorized employee should apply their own lock: This ensures that only the person who placed the lock can remove it.  

3. Apply Tagout Devices:

Attach tagout devices: Place tags on each lockout device.  

Include required information: Tags should include the name of the authorized employee who applied the tag, the date and time of application, and a warning not to energize the circuit.  

Use standardized tags: Use tags that are easily visible and durable.

4. Verify Isolation:

Test the circuit: Use a voltage tester to verify that the circuit is de-energized.  

Test between all phases and to ground: This ensures that no residual voltage or backfeed is present.

Attempt to operate the equipment: After verifying with a voltage tester, attempt to operate the equipment to assure that it will not function.

Address stored energy: If the circuit contains capacitors or other stored energy devices, discharge them according to manufacturer's instructions.

5. Release Stored Energy:

Capacitors: Discharge capacitors using appropriate grounding or shorting techniques.

Other stored energy: Release any other forms of stored energy, such as mechanical, hydraulic, or pneumatic energy, according to established procedures.

6. Ongoing Verification:

Periodic checks: During maintenance or repair work, periodically re-verify that the circuit remains de-energized.

If work stops: If the work is stopped for a long period of time, reverify the energy is still isolated before resuming work.

7. Removal of Lockout/Tagout Devices:

Authorized employee removal: Only the authorized employee who applied the lockout/tagout devices can remove them. 

Verification before re-energizing: Before removing the devices, verify that all personnel are clear of the equipment and that it is safe to re-energize the circuit.

Key Considerations:

Written Lockout/Tagout Program: Employers must have a written lockout/tagout program that outlines the procedures for controlling hazardous energy.

Employee Training: Employees must be trained on the lockout/tagout procedures and the hazards associated with electrical energy.  

Equipment-Specific Procedures: Develop equipment-specific lockout/tagout procedures for complex systems.

Regular Audits: Conduct regular audits of the lockout/tagout program to ensure its effectiveness.

Unexpected Startup and Electrocution:

Accidental Re-energization: Someone could unknowingly turn the switch back on, re-energizing the circuit and exposing workers to live voltage.

Remote or Automatic Activation: Some systems have remote or automatic activation mechanisms that can bypass the switch, re-energizing the circuit without anyone physically touching it.

Fatal Shock: If a worker is in contact with the equipment or wiring when it's re-energized, they could suffer a fatal electric shock.

Arc Flash and Burns:

Arc Flash Incident: If the circuit is re-energized while a worker is performing maintenance or repairs, it can trigger an arc flash.

Severe Burns: An arc flash generates intense heat, which can cause severe burns to the skin and eyes.  

Clothing Ignition: The heat can also ignite clothing, further exacerbating burn injuries.  

Equipment Damage and Fire:

Equipment Malfunction: Re-energizing the circuit while components are disassembled or disconnected can cause equipment malfunctions, leading to damage or failure.

Electrical Fire: A sudden surge of electricity can cause a short circuit or overload, leading to an electrical fire.

Explosion: In environments with flammable materials, an arc flash or electrical fire can trigger an explosion.  

Mechanical Injuries:

Moving Parts Activation: If the circuit powers mechanical equipment with moving parts, re-energization can cause those parts to suddenly activate.

Crushing or Entanglement: Workers could be crushed, entangled, or struck by moving parts.

Impact Injuries: Tools or materials could be propelled by the sudden activation, causing impact injuries.

Secondary Hazards:

Falls from Heights: If the re-energized circuit powers equipment at height, a sudden activation can cause a worker to lose their balance and fall.

Chemical Exposure: If the re-energized circuit powers equipment that handles chemicals, a malfunction can lead to a spill or release of hazardous substances.

Confined Space Hazards: If the circuit powers equipment within a confined space, an unexpected startup can complicate rescue efforts or introduce additional hazards.

Psychological Trauma:

Near-Miss Incidents: Even if no physical injury occurs, a near-miss incident can cause significant psychological trauma for workers.

Fear and Anxiety: Workers may develop fear and anxiety about working with electrical equipment, leading to decreased productivity and morale.

Why a Switch is Not Enough:

Switches Can Be Accidentally Turned On: Switches are easily accessible and can be accidentally turned on by anyone.

Switches Don't Always Isolate All Energy Sources: Some equipment may have backup power supplies or stored energy that bypasses the switch.

Switches Don't Provide Visual Confirmation: A switch in the "off" position doesn't provide clear visual confirmation that the circuit is de-energized.

The Importance of LOTO:

• LOTO procedures provide a systematic way to isolate and de-energize circuits, preventing accidental re-energization.  

• LOTO ensures that only authorized personnel can re-energize the circuit, and only after it has been verified to be safe.

• LOTO provides visual confirmation that the circuit is de-energized, reducing the risk of human error.