Why Are Porcelain Bushings Commonly Used in High-Voltage Transformers?

—A Comprehensive Analysis of the Key Role of Insulation Guardians

At the heart of high-voltage power systems, transformers act as the energy transmission hub. The critical "arterial interface" connecting this hub to the external "blood vessels" (transmission lines) is often the shiny, robust ceramic component—the porcelain bushing. Why do power grid engineers worldwide trust this traditional ceramic material as the gateway for high-voltage connections? This article delves into the scientific principles and engineering wisdom behind this choice.

Content

1. Superior Insulation Performance: The Key to Withstanding High Voltage

The potential difference between high-voltage transformer terminals and the ground can reach hundreds of kilovolts (e.g., 500kV or higher). The top priority is to reliably prevent current leakage to the ground or surface flashover. The winning features of porcelain materials include:

● Ultra-High Resistivity and Dielectric Strength:
– The volume resistivity of electrical porcelain typically                    ranges from 10¹² to 10¹⁴ Ω·cm (at room temperature), meaning it inherently resists current flow exceptionally well.
– Its dielectric strength (breakdown field strength)can  reach 10-20 kV/mm or higher, indicating that porcelain can withstand extremely high electric fields per unit thickness without breaking down.
– Cause and Effect: The dense, highly crystalline structure  of porcelain contains minimal free electrons, making ion migration difficult and preventing conductive pathways. Under extreme voltage, its atomic structure maintains strong binding forces, stopping electron avalanche breakdown.

● Excellent Surface Withstand Voltage Performance:
– Porcelain bushings feature multi-level sheds (fluted designs) on their outer surface.
– Cause and Effect:

(1)Increased Creepage Distance:The sheds significantly extend the path length required for current to travel along the surface from the high-voltage end to the grounded flange (low-voltage end).

(2)Prevents Continuous Water Film Formation:During rain or fog, the shed structure breaks up water into isolated droplets rather than a continuous conductive film, greatly improving wet flashover voltage.

(3)Enhances Pollution Flashover Resistance:In industrial or coastal areas, pollutants can accumulate and form conductive layers when wet. The shed design increases leakage path resistance and disrupts continuous pollution layers.

Table 1: Key Electrical Properties of Typical Bushing Insulation Materials

2. Exceptional Mechanical Strength: The Foundation of Support and Protection

Bushings must withstand:

(1)The weight and electromagnetic forces of internal conductors (especially during short-circuit events).

(2)External wind, ice, snow, and seismic loads.

(3)Transportation, installation shocks, and vibration stresses.

 Porcelain’s Robust Assurance:

(1) High Compressive Strength:
 – Premium electrical porcelain has a compressive strength of 500-800 MPa or higher.
– Cause and Effect:Porcelain is sintered from rigid silicate minerals (quartz, feldspar, mullite crystals) at high temperatures, forming a dense, interlocked microstructure that resists external pressure. This ensures stable support for heavy conductors and external loads.

(2)Good Flexural Strength:
– Electrical porcelain typically has a flexural strength of 50-100 MPa.
– Cause and Effect:Although brittle, modern porcelain is optimized through material formulas (e.g., alumina additives) and manufacturing (uniform firing, stress relief) to meet bending strength requirements. Flange and shed designs further optimize stress distribution.

3. Outstanding Environmental Resistance: Defying Harsh Conditions

Outdoor bushings operate reliably for decades under extreme conditions: sunlight, UV radiation, temperature swings (-40°C to +40°C or wider), rain, ice, salt spray, industrial pollutants, and sand abrasion.Porcelain’s Natural Armor:

● Excellent Weather and Aging Resistance:
Porcelain is an inorganic, non-metallic material with         ultra-stable composition.

(1)UV Resistance: Unlike organic polymers (e.g., rubber, plastics), porcelain’s high bond energy prevents UV-induced degradation.

(2)Thermal Shock Resistance:Low thermal expansion and uniform material properties prevent cracking under rapid temperature changes (validated per IEC 60137).

(3)Chemical Inertness: Resists acids, alkalis, salt spray, and most pollutants without corrosion.

(4)Hydrophobicity and Self-Cleaning (Glazed Surface): A smooth glaze enhances water repellency, promoting droplet runoff and reducing pollution buildup.

4. Superior Thermal Stability and Conductivity: Effective Heat Management

Bushings must dissipate heat from conductor losses (I²R) and internal insulation (oil or SF6 gas) to prevent localized overheating and insulation failure.

Porcelain’s Heat Management:
(1) High-Temperature Resistance and Low Thermal         Expansion:
– Porcelain is sintered at >1300°C but operates below 150°C, ensuring thermal stability.
– Its thermal expansion coefficient is low and uniform (3-                            6 × 10⁻⁶ /K), minimizing thermal stress.
(2) Moderate Thermal Conductivity:
– Porcelain’s thermal conductivity (1-2 W/(m·K))   

– outperforms air or most polymers (<0.5 W/(m·K)), aiding natural convection/radiation cooling.

5. Reliable Sealing: Safeguarding Internal Insulation

For oil-filled transformers, bushings seal the oil-air interface. For dry or SF6 gas bushings, they maintain gas integrity. Leakage risks insulation failure or explosions.

Porcelain’s Sealing Solutions:
● Metal-Ceramic Hermetic Sealing:
– Conductor terminals (copper/aluminum) and flanges (cast iron/steel) are bonded to porcelain via high-temperature sintering or mechanical compression with seals.
– Cause and Effect:These proven methods (per IEC/IEEE standards) endure thermal cycles and pressure changes, ensuring decades of leak-free operation.
● Simpler Design: 

Compared to composite or epoxy bushings, porcelain’s "ceramic tube + metal flange" design has fewer sealing points, reducing leakage risks.

Table 2: Comparison of High-Voltage Transformer Bushing Types

In Summary

Porcelain bushings dominate high-voltage transformers due to their unmatched insulation, mechanical strength, environmental resilience, thermal management, sealing reliability, and cost-effectiveness. While newer materials (e.g., composites) gain traction in medium/low-voltage applications, porcelain remains the top choice for ultra-high-voltage outdoor environments, backed by decades of proven performance.

Choosing porcelain bushings means building an indestructible defense line for long-term transformer safety and reliability.

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LuShan, est.1975, is a Chinese professional manufacturer specializing in power transformers and reactors for50⁺ years. Leading products are single-phase transformer, three-phase isolation transformers, electrical transformer, distribution transformer, step down and step up transformer, low voltage transformer, high voltage transformer, control transformer, toroidal transformer, R-core transformer;DC inductors, AC reactors, filtering reactor, line and load reactor, chokes, filtering reactor, and intermediate, high-frequency products.

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