Characteristics Pre-filled, high mechanical strength,...
What Electrical Epoxy Resin Actually Is Electrical epoxy resin is a two-component thermosetting polymer system formulated specifically to insulate, protect, and mechanically stabilize electrical and electronic components. Once a resin base is combined with a hardener, the mixture cures into a rigid...
Epoxy Insulating Glue Is the Preferred Choice for Electronics Protection For protecting sensitive electronic assemblies from electrical shorts, moisture, and mechanical stress, epoxy insulating glue offers the most reliable and versatile solution. Its combination of high dielectric strength, stron...
Executive Summary: The Direct Answer The best high thermal conductivity epoxy resin is selected by matching thermal conductivity (≥2.0 W/m·K) with viscosity (<50,000 cP) and glass transition temperature (Tg ≥ 120°C) for your specific application, while verifying the filler type (boron nitride vs...
“ From this year “
Shanghai Xrun Resin Co., Ltd., a professional leader in electrical insulation, specializes in R&D and production of epoxy resin systems for HV products. With two Shanghai-based factories (Jiading & Songjiang) boasting >50,000 tons/year capacity, automatic production lines, and a dedicated R&D Institute, Xrun has supplied >180,000 tons of epoxy materials. As a key player in national epoxy domestication projects, its 100% photovoltaic-powered green factories set the benchmark for high-voltage insulation innovation.
For 1100 kV ultra-high voltage (UHV) equipment, epoxy composites demand exceptional dielectric strength, thermal conductivity, and partial discharge resistance. Key technical requirements include:
Al₂O₃ (alumina) and SiO₂ (silica) nanoparticles are prime candidates. Below is a comparative parameter table:
| Parameter | Al₂O₃ Nanoparticles | SiO₂ Nanoparticles |
| Particle size (typical) | 30-80 nm | 20-50 nm |
| Thermal conductivity (W/m·K) | 30-36 (bulk), composite ~2.8-3.2 | 1.3-1.5 (bulk), composite ~1.8-2.2 |
| Dielectric constant (1 MHz) | ~9-10 | ~3.8-4.2 |
| Surface reactivity | Moderate (needs silane coupling) | High (easily functionalized) |
| Breakdown strength enhancement | +25-35% at 5-7 wt% | +30-40% at 3-5 wt% |
| Partial discharge resistance | Excellent (high thermal stability) | Good (better interface bonding) |
Process challenge: Nanoparticle agglomeration. For 1100 kV, uniform dispersion is critical. Shanghai Xrun Resin Co., Ltd. uses proprietary three-roll milling and ultrasonic-assisted mixing to achieve ≤50 nm agglomerate size. Uncontrolled agglomeration raises local field stress by >50%, leading to premature failure.
Common curing agents for UHV epoxy include anhydrides (e.g., methylhexahydrophthalic anhydride) and amines. Stoichiometric ratio (epoxy:hardener) directly impacts free volume, glass transition temperature (Tg), and high-field conductivity.
Shanghai Xrun Resin Co., Ltd. employs automatic digital mixing lines ensuring ±0.5% ratio accuracy. Deviations >2% cause:
Key challenge: Nanoparticles alter cure kinetics. Al₂O₃ surfaces accelerate anhydride reactions, requiring cure cycle adjustment (lower post-cure temperature from 160°C to 140°C, extend time by 2 hours). SiO₂ may inhibit cure if not properly silanized; unmodified SiO₂ reduces crosslink density by 15-20%.
Beyond formulation, industrial-scale production poses unique hurdles:
Shanghai Xrun Resin Co., Ltd. has overcome these via automatic production lines for resin, hardener, filler, and auxiliaries, with real-time rheology monitoring. Their two factories, fully covered by photovoltaic power, ensure sustainable, high-quality output for national UHV projects.
For ultra-high voltage (UHV) applications above 800 kV, Epoxy Resin For HV Electrical must meet stringent dielectric requirements to ensure safe and reliable operation of bushings, spacers, and transformers. Shanghai Xrun Resin Co., Ltd., a professional leader in electrical insulation, has supplied over 180,000 tons of epoxy materials and undertaken national projects for epoxy domestication. With two green factories (Jiading & Songjiang) fully powered by photovoltaics and an R&D Institute, Xrun excels in formulating high-performance epoxy resin systems for HV products.
At ≥800 kV, localized field stress can exceed 3-5 kV/mm. The epoxy must withstand >30 kV/mm (AC) without failure.
High tan δ causes dielectric heating and thermal runaway. For UHV, tan δ at 50 Hz and 90°C must be ≤0.002.
Leakage current must be minimized to avoid partial discharge (PD).
| Property | Standard Epoxy (≤245 kV) | UHV Epoxy (>800 kV, Xrun Grade) |
|---|---|---|
| Volume resistivity at 25°C | 1×1014 Ω·cm | ≥5×1015 Ω·cm |
| Volume resistivity at 100°C | 5×1012 Ω·cm | ≥2×1013 Ω·cm |
| Dielectric strength (AC, 1mm) | 20-25 kV/mm | ≥35 kV/mm |
| tan δ at 100°C (50 Hz) | 0.005-0.008 | ≤0.002 |
PD inception voltage (PDIV) must exceed 1.5× rated voltage. For 800 kV, PDIV > 1200 kV peak.
Under polluted conditions, high-voltage tracking resistance (IEC 60587) is critical. Minimum 1A 4.5 kV level required.
Above 800 kV, ohmic and dielectric losses generate heat. Thermal conductivity ≥2.0 W/m·K is mandatory to avoid hot spots.