Composite insulators are critical components in modern power systems. The following sections examine the root causes of their failures and present practical countermeasures.

Improper Handling

1. Mechanical Damage

·Core Rod Fractures: Excessive bending of the fiberglass-reinforced epoxy core rod beyond its tolerance can induce microcracks, significantly compromising mechanical integrity.

·Shed Damage: Flexible silicone rubber sheds are vulnerable to cuts or tears when exposed to sharp tools or abrasive surfaces during handling.

2. Sealing Failure

·Poor sealing at end fittings or cracks in the silicone housing allows acidic contaminants (e.g., acid rain, industrial pollutants) to penetrate.

·Prolonged acid exposure embrittles the core rod, potentially triggering catastrophic fractures and conductor drops.

3. Typical Scenarios

·Transport: Insufficient securing during transit leading to impact damage.

·Installation: Rough handling (dragging, hammering) or improper tool use causing localized stress concentrations.

External Force Damage

·Shed/housing damage: Construction impacts, bird pecking (magpies/crows), animal chewing (squirrels), or entanglement (kite strings/branches).

·Core rod fractures: Extreme weather (gales/ice storms) creating excessive conductor tension or direct human vandalism (gunshots/thrown objects).

Protection Measures:

·Requires special bird deterrents near wetlands/farmland towers.

·Requires vegetation management in forested areas to prevent treefall impacts.

Manufacturing Defects

·Insufficient mechanical strength: Improper glass fiber ratio or inadequate curing during production.

·Interface breakdown & brittle fracture: Voids in core rod-end fitting connections or microcracks propagating over time.

·Silicone rubber degradation: Insufficient UV stabilizers/anti-oxidants leading to surface chalking/cracking.

Electrical Flashover Fault

1. Lightning Flashover

·Damage pattern: Arc traces carbonizing sheds and burning grading rings.

·High-risk areas: Lightning-prone zones with inadequate tower grounding.

2. Rain Flashover

·Trigger conditions: Conductive pollution layers activated by low-resistivity rain (acid rain).

·Vulnerability: Insulators designed for clean areas fail in polluted environments.

3. Pollution Flashover

·Industrial/salt contamination accumulation

·Moisture (fog/drizzle) dissolves pollutants into conductive films.

Silicone advantage: Hydrophobicity delays but does not eliminate, the risk under heavy contamination.

4. Bird Streamer Flashover

·Physics: Bird excrement bridges sheds, creating parallel conduction paths.

·High-risk species: Large birds (eagles/storks) or flocking birds (crows).

Key Indicators of Composite Insulator Aging

Degradation Drivers:

·Environmental: ultraviolet (UV)-induced polymer breakdown, thermal cycling cracks, humidity-assisted corrosion.

·Electrical: Partial discharges (corona/arcing) eroding shed surfaces.

Aging Symptoms:

· Hardened, cracked sheds with reduced elasticity

· Weight loss and density changes in core rods

Additional Risk Factors for Composite Insulator Aging

Design/Selection Errors:

·Insufficient creepage distance for polluted areas

·Stress-concentrating end-fitting designs

Maintenance Gaps:

·Inadequate cleaning cycles

·Underutilized diagnostic tools (IR thermography/UV imaging)

Composite Insulator Prevention Matrix

Proactive multi-layer controls can significantly reduce composite insulator failure rates, ensuring grid reliability. Regular insulator inspections (recommended every 3-5 years) with timely replacement of degraded units are critical for preventive maintenance.

For product specifications or technical consultation: info@tcipower.com