GIS Voltage Transformer Technology Optimization Solution: Technological Innovation Enhancing Insulation Performance and Measurement Accuracy

ROCKWILL

07/11/2025

Ⅰ. Analysis of Technical Challenges

Traditional GIS (Gas-Insulated Switchgear) voltage transformers face two core problems in complex grid environments:

Insufficient Insulation System Reliability

SF₆ gas impurities (moisture, decomposition byproducts) cause surface discharges, leading to insulation degradation.
Temperature fluctuations (-40°C to +80°C) cause gas density changes, reducing partial discharge inception voltage (PDIV).

Measurement Accuracy Degradation

Temperature drift of core permeability (typical drift: 0.05%/K).
System frequency fluctuations (±2Hz) cause ratio/phase angle errors to exceed limits.

Field data indicates: Conventional devices can exhibit measurement errors up to class 0.5 under extreme conditions, with an annual failure rate exceeding 3%.

II. Core Technical Optimization Solutions

(1) Nano-Composite Insulation System Upgrade

Technical Module	Implementation Points
Nano Insulation Material	Al₂O₃-SiO₂ nano-composite coating (particle size: 50-80nm) used to enhance epoxy resin surface tracking resistance by ≥35%.
Hybrid Gas Optimization	SF₆/N₂ (80:20) mixture filling, lowering liquefaction temperature to -45°C and reducing leakage risk by 40%.
Enhanced Sealing Design	Metal bellows dual-seal structure + laser welding process, leakage rate ≤ 0.1%/year (IEC 62271-203 standard).

Technical Validation: Passed 150kV power-frequency withstand voltage test and 1000 thermal cycles; partial discharge level ≤3pC.

(2) Full-Condition Digital Compensation System

A[Temperature Sensor] --> B(MCU Compensation Processor)

C[Frequency Monitoring Module] --> B(MCU Compensation Processor)

D[AD Sampling Circuit] --> E(Error Compensation Algorithm)

B(MCU Compensation Processor) --> E(Error Compensation Algorithm)

E(Error Compensation Algorithm) --> F[Class 0.2 Standard Output]

Core Algorithm Implementation:
ΔUcomp=k1⋅ΔT+k2⋅Δf+k3⋅e−αt\Delta U_{comp} = k_1 \cdot \Delta T + k_2 \cdot \Delta f + k_3 \cdot e^{-\alpha t}ΔUcomp=k1⋅ΔT+k2⋅Δf+k3⋅e−αt
Where:

k1k_1k1 = 0.0035/°C (Temperature Compensation Coefficient)
k2k_2k2 = 0.01/Hz (Frequency Compensation Coefficient)
k3k_3k3 = Aging Attenuation Compensation Factor

Real-time correction response time <20ms; operational temperature range extended to -40°C ~ +85°C.

III. Quantitative Benefit Forecast

Metric Item	Conventional Solution	This Technical Solution	Optimization Magnitude
Measurement Accuracy Class	Class 0.5	Class 0.2	↑150%
PD Inception Voltage (PDIV)	30kV	≥50kV	↑66.7%
Design Life	25 years	>32 years	↑30%
Annual Inspection Frequency	2 times/year	1 time/year	↓50%
Lifecycle O&M Cost	$180k/unit	$95k/unit	↓47.2%

IV. Technical Validation Results

Type Test Data (3rd Party Certified):

Temperature Cycling Test: After 100 cycles (-40°C ~ +85°C), ratio error change < ±0.05%.
Long-Term Stability: After 2000h accelerated aging test, error shift ≤ 0.05 class.

Demonstration Project (750kV Substation):
Zero failure records after 18 months of operation. Maximum measured error: 0.12% (outperforming class 0.2 requirements).

V. Engineering Implementation Path

Equipment Customization Cycle:

Solution Design (15 days) → Prototype Manufacturing (30 days) → Type Testing (45 days)

Field Upgrade Solution:

Compatible with existing GIS gas chamber interfaces (Flange standard IEC 60517).
Outage replacement time ≤ 8 hours.

Smart O&M Support:

Built-in H₂S/SO₂ micro-environment sensors.
Supports IEC 61850-9-2LE digital output.