How to Select Paper Covered Wire for Transformer Windings: A Complete Selection Guide


How to Select Paper Covered Wire for Transformer Windings: A Complete Selection Guide

Transformers are the “heart” of power systems, and paper-covered wire (PCW) is one of the core insulation materials for both oil-immersed and dry-type transformer windings. From low-voltage distribution transformers (0.4 kV) to ultra-high-voltage power transformers (1000 kV), from residential power distribution to special transformers such as electric furnaces, traction, and rectification, paper-covered wire has long held a dominant position as the mainstream transformer winding insulation material due to its advantages such as oil-immersion compatibility, controllable cost, and selectable temperature resistance (105°C / 130°C / 155°C / 180°C / 200°C / 220°C).

I. Introduction: Why Paper-Insulated Wire Remains the Mainstream Insulation for Transformer Windings

1.1 The role of paper-insulated thread in transformer

In a transformer structure, the winding is the “heart of the heart”—directly responsible for the three core tasks of voltage establishment, energy transfer, and short-circuit withstand. The choice of insulated wire (magnet wire/winding wire) for the winding determines the transformer’s insulation class, life curve, overload capacity, and manufacturing cost. Paper-insulated wire is a winding wire made of round or flat copper wire as the conductor, wrapped with one or more layers of insulating paper tape. An enamel coating (enamel + paper composite structure) can be added to enhance overall performance.

1.2 Core Advantages of Paper-Insulated Wire Compared to Enameled Wire / Fiberglass-Insulated Wire

  • Fully Transformer Oil Compatible: The kraft paper/cable paper/Nomex aramid paper used in paper-insulated wire does not precipitate or produce gas in Transformer oil, ensuring no oil contamination during long-term operation. – High and Stackable Breakdown Voltage: Single-layer 0.05–0.13 mm kraft paper has a breakdown voltage of 600–1500 V; multi-layer (double/triple) windings have linearly stacked breakdown voltages. – significantly Lower Price Than Enameled/Fiberglass: Under the same conductor specifications, paper-insulated wire costs 20–50% more than pure enameled wire but 30–60% less than fiberglass-insulated wire. – Mature Winding Technology: Continuous, spiral, disc, and layered windings can all be used.

1.3 Five Typical Application Scenarios

II. Core Structure and Material System of Paper-Insulated Wire

No.Application ScenarioMain Insulation Paper TypeTypical Temperature Resistance
1Oil-immersed power transformer (10–500 kV)Cable paper + High-voltage cable paper105°C (Class A)
2Dry-type transformer (resin casting/impregnation)NOMEX 410 / HPI-Green180–220°C (Class H / Class C)
3Instrument transformer (CT / PT / CVT)Telephone paper + Cable paper105–130°C
4Reactor (current limiting / filtering / parallel connection)NOMEX 410 / DuPont paper155–180°C
5Special transformer (electric furnace / traction / rectification)Composite paper + NOMEX155–220°C

2.1 Conductors: round wire / flat wire / copper / aluminum

Paper-insulated wire conductors can be divided into two categories: round wire and flat wire.

  • Round wire: Diameter 1.0–7.0 mm, suitable for layered windings, low-voltage windings, and small-capacity transformers. – Flat wire: Width 2.0–16.0 mm, thickness 0.8–5.6 mm, suitable for disc windings, high-voltage windings, and large-capacity transformers. – Materials: Oxygen-free copper rod (TU1 / TU2), electrical round aluminum rod (1060 / 1350). Aluminum wire costs approximately 1/3 the price of copper wire and weighs approximately 1/2 the weight.

Key Note: Flat wire windings offer significantly better heat dissipation performance than round wire windings in high-current applications, but require more sophisticated winding processes.

2.2 Insulation Structure: Three Typical Combinations

StructureCompositionApplication ScenarioBreakdown Voltage
Paper-Insulated Bare WireConductor + 1–3 layers of paper tapeLow-voltage winding600–4500 V
Paper-Insulated Enameled WireConductor + enamel film + 1–2 layers of paper tapeMedium-voltage winding, instrument transformer2000–8000 V
Composite Insulation (paper + enamel + fiberglass)Conductor + enamel film + paper tape + fiberglassDry-type transformer, special transformer5000–12000 V

2.3 Insulating Paper Materials: Four Main Types

2.3.1 Kraft Paper

  • Thickness: 0.05–0.13 mm – Breakdown Voltage: 8–10 kV/mm – Temperature Resistance: 105°C (Class A) – Price: Low (≈ 30–50 RMB/kg) – Applications: Oil-immersed power transformer low-voltage windings, instrument transformers

2.3.2 Cable Paper (High Voltage Cable Paper)

  • Thickness: 0.08–0.17 mm – Breakdown Voltage: 10–14 kV/mm – Temperature Resistance: 105°C (Class A) – Features: High density, low permeability, minimal gas evolution in oil – Applications: Oil-immersed power high-voltage windings (35 kV / 110 kV / 220 kV)

2.3.3 NOMEX Aramid Paper (DuPont T410 / T414)

  • Thickness: 0.05–0.76 mm – Breakdown Voltage: 18–30 kV/mm – Temperature Resistance: 220°C (Class C, UL certified up to 220°C) – Price: High (≈ 600–1200 RMB/kg) – Features: Oil resistant, radiation resistant, flame retardant (UL 94 V-0), fully compatible with transformer oil – Applications: Dry-type transformers, reactors, rail traction transformers, wind turbines

2.3.4 HPI-Green / Marker Paper

  • HPI-Green: High-power insulating paper, 180–200°C, suitable for dry-type transformer insulation cylinders and laminates. – Mark Paper: Thin (0.05 mm) marking paper for marking the start and end points of windings.

2.4 Number of Paper Layers and Insulation Thickness

  • Single-layer paper sheath: Insulation thickness 0.05–0.13 mm, breakdown voltage 600–1500 V (low voltage) – Double-layer paper sheath: Insulation thickness 0.16–0.30 mm, breakdown voltage 2000–3000 V (medium voltage) – Triple-layer paper sheath: Insulation thickness 0.24–0.50 mm, breakdown voltage 3500–4500 V (high voltage)

The dimensional increment (mm) caused by paper tape wrapping shall meet the requirements of IEC 60317: tolerance of -100% when single-layer increment is ≤ 0.50 mm; -7.5% when increment is 0.50–1.25 mm; and -50% when increment is > 1.25 mm.

III. transformer Classification and Paper Wire Selection Strategy

3.1 Oil-Immersed Power Transformer

Oil-immersed transformers are the mainstay of the power grid, with single-unit capacities ranging from 50 kVA to 1000 MVA, and voltage levels covering 10 kV – 1000 kV.

  • Insulation Class: Class A (105°C), made of transformer oil with insulating paper. – Main Paper Types: Cable paper, high-voltage cable paper. – Typical Selections: – Low-voltage winding (≤ 1 kV): Paper-insulated enameled round copper wire, 1 layer of 0.08 mm cable paper. – Medium-voltage winding (10–35 kV): Paper-insulated enameled flat copper wire, 2 layers of 0.13 mm cable paper. – High-voltage winding (110–500 kV): Paper-insulated enameled flat copper wire, 3 layers of 0.13 mm high-voltage cable paper. – Key Standards: GB/T 1094.2 (Oil-immersed transformer temperature rise), IEC 60076-2, IEC 60317-27 (Aluminum wire) / IEC 60317-27-2 (Round aluminum).

3.2 Dry-Type Transformer

Dry transformers use air or solid resin as the insulating medium and are commonly found in high-fire-resistance environments such as buildings, subways, airports, and mines.

  • Insulation Classes: Class F (155°C), Class H (180°C), Class C (200°C) – Main Paper Types: NOMEX 410/414, PI film – Typical Selections: – Distribution type (≤ 2500 kVA): NOMEX 410 single-layer paper-insulated round/flat copper wire – Power type (2500 kVA–10 MVA): NOMEX 410 double-layer paper-insulated flat copper wire – Special dry-type (e.g., tunnel boring machines, subways): NOMEX 410 + fiberglass composite insulation – Key Standards: IEC 60076-11, GB/T 1094.11, IEEE C57.12.01

3.3 Current Transformers (CT / PT / CVT)

Instrument transformers are key equipment for metering and protection in power systems, requiring high precision, high stability, and long lifespan.

  • Insulation Class: Class A (Oil-Immersed CT/PT) / Class BE (Dry Type) – Dominant Paper Type: Telephone Paper + Cable Paper / NOMEX – Typical Selection: – Oil-immersed CT below 35 kV: 0.5–2.5 mm round copper wire, 2 layers of 0.05 mm telephone paper – 110 kV Oil-immersed CT: 1.6 × 4.0 mm flat copper wire, 2 layers of 0.08 mm cable paper – Dry-type CT/PT: NOMEX 410 single-layer paper sheath – Key Parameters: Turn-to-turn insulation, creepage distance, secondary impedance matching

3.4 Reactors (Current Limiting/Filtering/Parallel/Arc Suppression Coil)

Reactors operate under high current for extended periods, making heat dissipation a key challenge.

  • Insulation Class: F / H / C – Main Paper Type: NOMEX 410 / DuPont Paper / Fiberglass Paper Composite – Typical Selections: – Dry-core Reactors: NOMEX 410 Paper-insulated Flat Copper Wire – Air-core Reactors: NOMEX 410 + Fiberglass Composite – Shunt Reactors (500 kV and above): NOMEX 410 Double Layer + Resin Casting – Key Standards: IEC 60076-6, GB/T 1094.6

IV. Key Performance Indicators and Acceptance Parameters

4.1 Electrical Performance

4.1.1 Breakdown Voltage

  • Single-layer 0.05 mm kraft paper: ≥ 600 V – Single-layer 0.08 mm cable paper: ≥ 1000 V – Single-layer 0.13 mm cable paper: ≥ 1500 V – Single-layer 0.25 mm NOMEX 410: ≥ 5000 V

4.1.2 Dielectric Loss Tangent (tan δ)

  • Dry cable paper: tan δ ≤ 0.005 (50 Hz) – Oil-impregnated cable paper: tan δ ≤ 0.003 (50 Hz) – The lower this value, the lower the no-load loss and reactive power loss of the transformer.

4.1.3 Partial Discharge (PD)

  • Oil-immersed transformer windings: ≤ 10 pC (at 1.5 times rated voltage) – Dry-type transformers: ≤ 5 pC

4.2 Mechanical Properties

  • Conductor elongation (round wire): ≥ 25% (copper) / 15% (aluminum) – Conductor tensile strength: 220–280 MPa (copper, soft state) – Paper tape tightness: Visually free of curling and wrinkles; peel strength ≥ 0.5 N/cm

4.3 Chemical and Aging Properties

  • Transformer Oil Compatibility: Breakdown voltage drop ≤ 10% after aging at 85°C / 168 h. – Moisture Content (at factory): ≤ 6% (kraft paper/cable paper). – Thermal Aging Life: Class A (105°C) 20 years of continuous operation; Class H (180°C) 15+ years of continuous operation.

V. Standards System and Procurement Specifications

5.1 International Standards

StandardScopeRemark
IEC 60317-0-1:2013General requirements for round copper winding wireBenchmark for all paper-covered round copper wire
IEC 60317-0-2General requirements for round aluminum winding wire
IEC 60317-0-3:2008 + AMD1:2013Round aluminum winding wire (before paper covering)Nominal diameter 0.5–5.0 mm
IEC 60317-27 / 27-2Paper tape covered round aluminum winding wireSpecifically for oil-immersed transformers
IEC 60317-56FIW fully insulated defect-free enameled wire
IEC 60554-1 / 60554-3-5Specification for electrical insulating paper materialsBenchmark for paper-based materials
NEMA MW 1000-2018American comprehensive magnet wire standardIncludes paper-covered aluminum (220°C)
IEEE C57.12.00 / C57.12.01Dry-type / liquid-immersed transformer

5.2 National/Industry Standards

| Standard | Scope | |——|——| | GB/T 1094.1–11 | Electrical Transformer (Capacity/Temperature Rise/Insulation Level/Dry Type) | | GB/T 7673.1–3 | Paper-Insulated Round Copper/Round Aluminum/Flat Wire Windings | | GB/T 19290.1 | Dry Type Transformer NOMEX Paper-Insulated Wire (Reference) | | T/CEC 202-2019 | Guidelines for Selecting Corrugated Insulation Paper for Oil-Immersed Electrical Transformers | | JB/T 6302 / 8740 | Technical Conditions for Paper-Insulated Wire for Transformers |

StandardScope
GB/T 1094.1–11Power transformer (capacity / temperature rise / insulation level / dry-type)
GB/T 7673.1–3Paper-covered round copper / aluminum / flat wire winding wire
GB/T 19290.1Dry-type transformer NOMEX paper-covered wire (reference)
T/CEC 202-2019Selection guide for crepe insulating paper used in oil-immersed power transformers
JB/T 6302 / 8740Technical conditions for paper-covered wire used in transformers

5.3 Procurement Acceptance Checklist (PO Template)

  1. Conductor Specifications: Round wire diameter / Flat wire diameter (W × T) (mm)
  2. Conductor Material: TU1 oxygen-free copper / 1060 aluminum / 1350 aluminum
  3. Insulating Paper Type: Kraft paper / Cable paper / High voltage paper / NOMEX 410 / HPI-Green
  4. Number of Paper Layers and Thickness: 1L / 2L / 3L, 0.05–0.13 mm per layer
  5. Thermal Class: A (105°C) / E (120°C) / B (130°C) / F (155°C) / H (180°C) / C (200°C) / 220°C
  6. Breakdown Voltage: Single layer / Overall minimum
  7. Geometric Tolerance: Conductor + outer diameter after paper wrapping
  8. Roll Specifications: 30–150 kg 250500 / 250600 Wooden Pallets
  9. Standards: IEC / GB / NEMA / Bilateral Agreement
  10. Certifications: UL / CE / RoHS / REACH (Export Market)

VI. Paper-insulated Wire Selection Decision Process

6.1 Five-Step Selection Method

Step 1: Determine the transformer type (oil-immersed/dry-type/current transformer/reactor/special type) ↓

Step 2: Determine the voltage level (low voltage ≤ 1 kV / medium voltage 10–35 kV / high voltage 110–500 kV) ↓

Step 3: Select the thermal class (A / E / B / F / H / C) ↓

Step 4: Select the insulation paper type (kraft paper / cable paper / high voltage paper / NOMEX / HPI-Green) ↓

Step 5: Determine the conductor specifications (round / flat / copper / aluminum)

6.2 Selection Decision Table

Transformer TypeVoltage LevelRecommended Paper TypeTemperature ClassRecommended Conductor
Oil-immersed Distribution≤ 1 kV1L 0.08 mm Cable paper105°C (A)Round copper / round aluminum
Oil-immersed Distribution10 kV2L 0.13 mm Cable paper105°C (A)Round copper
Oil-immersed Power35 kV2L 0.13 mm HV paper105°C (A)Flat copper
Oil-immersed Power110 kV3L 0.13 mm HV paper105°C (A)Flat copper
Oil-immersed Power220–500 kV3L 0.17 mm HV paper105°C (A)Flat copper
Dry-type Distribution≤ 1 kV1L 0.25 mm NOMEX 410155–180°C (F/H)Round copper / round aluminum
Dry-type Power10–35 kV2L 0.25 mm NOMEX 410180°C (H)Flat copper
Instrument Transformer≤ 35 kV2L 0.05 mm Telephone paper105°C (A)Round copper
Reactor10–110 kV1L 0.25 mm NOMEX 410155–180°C (F/H)Flat copper
Rectifier / Furnace Transformer10–35 kV2L 0.25 mm NOMEX 410180–200°C (H/C)Flat copper
Traction Transformer25 kV2L 0.25 mm NOMEX 410 + Fiberglass180°C (H)Flat copper
Wind Power Transformer0.69–35 kV2L 0.25 mm NOMEX 410180–220°C (H/C+)Flat copper

6.3 Cost and Performance Balance

  • Cost Priority: aluminum conductor + kraft paper + oil-impregnated design (lowest cost, 20+ years lifespan) – Performance Priority: copper conductor + NOMEX 410 + dry design (highest cost, flame retardant + short-circuit resistant + 25+ years lifespan) – Balanced Solution: copper conductor + cable paper + oil impregnation (balances cost and reliability)

VII. Typical Failure Modes and Quality Control

7.1 Three Typical Failure Modes

7.1.1 Paper layer cracking/bubbling

  • Phenomenon: Localized blistering and cracking of the paper layer after oil impregnation of the winding – Causes: (1) Loose paper tape wrapping; (2) Insufficient drying before impregnation; (3) Excessive moisture content of the transformer oil – Solutions: Paper tape wrapping tightness ≥ 0.5 N/cm; Vacuum drying before impregnation ≤ 100 Pa / 80°C / 24 h

7.1.2 Inter-turn short circuit

  • Phenomenon: Inter-turn breakdown occurs during high-voltage testing or operation – Causes: (1) Paper layer damage (scratches during winding); (2) Long-term accumulation of partial discharge; (3) Failure of double insulation of the paper layer (enamel coating) – Countermeasures: Paper tape overlap rate ≥ 30%; 100% inter-turn pulse test; PD test ≤ 10 pC

7.1.3 Thermal Aging of Insulation

  • Phenomenon: After long-term operation, breakdown voltage decreases and oil quality deteriorates. – Causes: Hot spot temperature exceeds design limits (Class A 105°C, Class H 180°C); for every 6°C increase in hot spot temperature, the aging rate doubles. – Solutions: Real-time monitoring with fiber optic temperature measurement; online oil chromatography monitoring; controlling the load rate ≤ 0.8.

7.2 Five Key Points of Quality Control

  1. Incoming Quality Control (IQC): Conductor diameter, tape thickness, moisture content, breakdown voltage. 2. In-Process Quality Control (IPQC): Tape overlap, tightness, appearance, continuity. 3. Outgoing Quality Control (OQC): 100% inter-turn pulse test + sampling breakdown test. 4. Traceability: Each roll of wire is accompanied by batch number + furnace number + test report. 5. Third-Party Testing: UL / TÜV / Transformer Institute (Shenyang Transformer Institute / Xi’an High Voltage Apparatus Research Institute).

VIII. Procurement Strategy and Supplier Evaluation

8.1 Procurement Quantity and Delivery

  • Small batch customization (≤ 500 kg): Lead time 3–4 weeks, price 15–25% higher. – Medium batch (500–5000 kg): Lead time 2–3 weeks, standard price. – Large batch (≥ 5000 kg): Lead time 4–6 weeks (including raw material procurement), price can be reduced by 5–10%.

8.2 7 Dimensions of Supplier Evaluation

DimensionWeightKey Question
Qualification15%ISO 9001 / UL / CE / RoHS / REACH
Production Capacity15%Monthly output ≥ 50 tons / Equipment automation level
Quality20%Incoming material qualification rate ≥ 99.5% / Complaint response ≤ 24 h
Price15%Same-spec comparison / Tiered pricing / Payment terms
Delivery10%On-time delivery rate ≥ 95%
Technical15%Engineers ≥ 3 / Support selection / Issue technical agreement
Service10%After-sales response / On-site technical support / Return policy

8.3 Key Acceptance Points

  • Appearance: The paper tape is uniform, continuous, undamaged, wrinkle-free, and the ends are fixed. – Geometric: Conductor dimensions, outer diameter after paper wrapping, and paper tape overlap rate. – Electrical: 100% inter-turn testing + sampling breakdown testing (≥ IEC 60317 limit). – Mechanical: Elongation, tensile strength, and peel strength. – Aging: Sampling accelerated aging test (135°C / 168 h breakdown voltage retention ≥ 80%).

IX. Key Points for Installation, Operation and Maintenance

9.1 Winding Process

  • Winding speed: ≤ 30 rpm (to avoid scratching the paper layer) – Ambient humidity: ≤ 60% RH (to avoid moisture absorption of the paper layer) – Ambient temperature: 20–28°C – Winding tension: 5–15 N for round copper, 20–80 N for flat copper (depending on cross-section)

9.2 Impregnation and Drying

  • Pre-drying: 100 Pa / 80°C / 24 h – Vacuum oil impregnation: ≤ 50 Pa / 60°C / 12 h – Oil storage: Breakdown voltage ≥ 50 kV/2.5 mm; Moisture content ≤ 30 ppm

9.3 Operation Monitoring

  • Load Rate: Long-term ≤ 80%, Short-term (Emergency) ≤ 110% – Hotspot Temperature: Grade A ≤ 105°C, Grade H ≤ 180°C (fiber optic temperature measurement) – Oil Chromatography: Periodic detection of H₂ / CH₄ / C₂H₂ / C₂H₄ content – Partial Discharge: Online PD monitoring ≤ 10 pC

X. Future Trends: Environmental Protection, Energy Conservation, and New Paper Packaging Lines

10.1 Environmentally Friendly Insulating Oil and Bio-based Insulating Paper

  • Vegetable-based insulating oil (FR3 / Envirotemp): 360°C ignition point, CO₂ emissions reduced by 50%+, biodegradable. – Bio-based insulating paper: Replaces traditional kraft paper, reducing carbon footprint by 30%.

10.2 Energy-saving, low-loss paper-insulated line

  • Ultra-low resistance conductor: High-purity oxygen-free copper (99.99%), DC resistance reduced by 2–3%. – Low dielectric loss paper-based material: tan δ ≤ 0.002 (50 Hz), no-load loss reduced by 5–10%.

10.3 Intelligentization and Traceability

  • QR Code Traceability: Each roll of paper packaging fabric includes a QR code, allowing users to track production batches, test data, and transportation routes. – Digital Twin: Cloud-based management of the entire lifecycle data of the paper packaging fabric + transformer.

XI. Conclusion

The selection of paper-insulated wire in transformer windings is essentially a four-dimensional balance of “temperature + voltage + environment + cost”.

  • Oil-immersed power transformer → Cable paper/High-voltage paper + Round/Flat copper (Class A 105°C) – Dry-type transformer → NOMEX 410 + Round/Flat copper (Class F/H/C 155–220°C) – Instrument transformer → Telephone paper/Cable paper + Round copper (Class A 105°C) – Reactors and special transformers → NOMEX 410 + Fiberglass composite + Flat copper (Class H/C)

Five key points to consider when purchasing: (1) Conductor specifications and materials; (2) Insulation paper type and number of layers; (3) Thermal class; (4) Breakdown voltage and geometric tolerances; (5) Standard certifications (IEC / NEMA / GB / UL). Quality and lifespan take precedence over price—the lifespan of a 110 kV oil-immersed power transformer is typically required to be ≥ 30 years. Paper-insulated wire, as the core insulation material, must undergo rigorous incoming material inspection, process inspection, and factory inspection.

XII. Typical Case Analysis: Paper-Shelled Wire Selection in 3 Real-World Scenario

12.1 Case 1: 110 kV oil-immersed power transformer (50 MVA)

Project Background: A provincial power grid company’s 110 kV main transformer upgrade project, with a capacity of 50 MVA, low voltage 10.5 kV / high voltage 121 ± 2×2.5% kV, impedance voltage 10.5%, and Yyn0 connection.

Selection List: – High Voltage Winding (110 kV Side): Flat copper conductor 2.24 × 7.10 mm, enamel coating (PEI) + 3 layers of 0.13 mm high voltage cable paper – Medium Voltage Winding (38.5 kV Tap): Flat copper conductor 2.80 × 8.00 mm, enamel coating + 2 layers of 0.13 mm cable paper – Low Voltage Winding (10.5 kV Side): Copper foil conductor 1.40 × 350 mm, single layer of 0.10 mm cable paper – Winding Temperature Rise Limit: 65 K (Class A) – Insulation Level: LI 480 kV / AC 200 kV (High Voltage Winding)

Key Processes: 1. Vacuum Drying: ≤ 100 Pa / 110°C / 48 h 2. Vacuum Oil Injection: ≤ 50 Pa / 60°C 3. Insulating Oil: KI50X mineral oil, breakdown voltage ≥ 70 kV/2.5 mm 4. Partial Discharge Test: ≤ 10 pC at 1.5 × 110 / √3 = 95.3 kV

SupplierUnit Price (CNY/kg)Breakdown VoltageMoisture ContentComplaint Rate
Supplier A1454.2 kV (double layer)5.8%0.5%
Supplier B1383.8 kV (double layer)6.5%1.2%
Supplier C (LNPU)1424.5 kV (double layer)5.2%0.2%

Conclusion: Choose LNPU. Reasons: (1) Highest breakdown voltage; (2) Lowest moisture content; (3) Lowest customer complaint rate. Overall lifespan: 30+ years.

12.2 Case 2: 2.5 MVA Dry Transformer (Rail Transit Traction)

Project Background: A traction substation for Metro Line 2 in a certain city, dry-type transformer, 2.5 MVA, 35 kV / 1.18 kV, overload capacity 200% (30 s), forced air cooling.

Selection List: – High Voltage Winding (35 kV): Flat copper conductor 2.00 × 6.30 mm, PI enamel coating + 2 layers of 0.25 mm NOMEX 410 – Low Voltage Winding (1.18 kV): Copper foil 2.00 × 280 mm, PI enamel coating + 1 layer of 0.25 mm NOMEX 410 – Insulation Class: Class H (180°C) – Cooling Method: AN / AF dual-mode – Short-Circuit Impedance: 6.5%

Key Parameters: – Partial discharge: ≤ 5 pC – Noise level: ≤ 65 dB(A) – Flame retardant rating: UL 94 V-0

Operational Verification: – Starting inrush current 8 times rated current for 0.5 s: No deformation of the paper-insulated wire. – Continuous overload 1.5 times rated current for 4 h: Hot spot temperature 145°C < 180°C limit. – Lifetime assessment: > 30 years (based on IEEE C57.91 accelerated aging model).

12.3 Case 3: 35 kV Photovoltaic Boost Transformer (Outdoor Type)

Project Background: A 100 MW photovoltaic power station in Northwest China, with a 35 kV step-up transformer (SCB11-2500/35), suitable for both indoor and outdoor use, in a Gobi Desert climate (35°C diurnal temperature range, dust storms, and strong ultraviolet radiation).

Selection List: – High Voltage Winding (35 kV): Flat copper 1.80 × 5.60 mm, PI enamel coating + 2 layers of 0.25 mm NOMEX 410 + UV protective coating – Low Voltage Winding (0.8 kV): Copper foil 1.60 × 300 mm, PI enamel coating + 1 layer of 0.25 mm NOMEX 410 – Insulation Class: Class H (180°C) – Protection Class: IP54 (Outdoor)

Special Processes: – NOMEX paper with UV protective coating (epoxy acrylate) – Fiberglass binding tape (ends) – Vacuum pressure impregnation (VPI) + H-grade impregnation varnish

Reliability Verification: – Dust Test: Insulation resistance > 1000 MΩ after 96 hours of dust exposure. – UV Aging: NOMEX tensile strength retention ≥ 90% after 1000 hours of UV irradiation. – Thermal Cycling: No cracking after 100 cycles at -40°C to +85°C.

XIV. Glossary

TermEnglishExplanation
PCWPaper Covered WirePaper-covered winding wire
PCECWPaper Covered Enameled Copper WirePaper-covered enameled copper wire
PCEAWPaper Covered Enameled Aluminum WirePaper-covered enameled aluminum wire
CTCurrent TransformerCurrent transformer
PT / VTPotential Transformer / Voltage TransformerVoltage transformer
CVTCapacitor Voltage TransformerCapacitor voltage transformer
tan δDielectric Dissipation FactorDielectric loss tangent
PDPartial DischargePartial discharge
VPIVacuum Pressure ImpregnationVacuum pressure impregnation
NOMEXDuPont aramid paper trade name
Kraft PaperKraft paper (sulfate pulp paper)
Cable PaperCable paper
DMDDacron-Mylar-DacronPolyester fiber + polyester film composite paper
NMNNomex-Mylar-NomexNOMEX + polyester film composite paper
AN / AFAir Natural / Air ForcedNatural air cooling / forced air cooling

About LP Winding Wire (LNPU)

LNPU has over 30 years of experience in manufacturing transformer winding wires, with products covering:

  • Paper-insulated round copper/aluminum wire: 1.0–7.0 mm, 1–3 layers of kraft paper/cable paper/high-voltage paper. Paper-insulated flat copper/aluminum wire: Width 2.0–16.0 mm, thickness 0.8–5.6 mm, single/double/triple layer. Paper-insulated enameled composite wire: PEI/PAE/PI (enamel coating) + 1–2 layers of paper tape, breakdown voltage 8000 V+. NOMEX 410 paper-insulated wire: 220°C/UL 94 V-0, UL certified. Fiberglass paper-insulated composite wire: Class H 180°C, dry type (transformer)/wind power/traction.

Supported standards: IEC 60317, NEMA MW 1000-2018, GB/T 7673, UL, CE, RoHS, REACH. We provide one-stop service for sample testing, customization, and technical agreements.

For inquiries, please visit: https://lpenamelwire.com


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