Power Transformer 330 kV (Um=363kV)

Changzhou Pacific Electric Power Equipment Group’s 330kV power transformers feature low loss, low noise, high efficiency and strong reliability. Adopting advanced design and premium materials, they deliver excellent insulation, low partial discharge and high short‑circuit withstand strength. With stable performance, long service life and compact structure, our transformers are widely used in power grids, industrial and infrastructure projects. They ensure safe and stable operation under various working conditions, providing reliable power solutions for customers worldwide.

Introduction to 330kV (Um=363kV) Power Transformer

Our company's 330kV power transformer (with system maximum voltage Um=363kV) is suitable for ultra-high voltage transmission systems of 330kV. The product is designed to further enhance insulation coordination and mechanical stability, ensuring low loss, low partial discharge, and high operational reliability. The core is made of high-performance silicon steel sheets, with a sturdy binding and clamping system. The coil design undergoes multiple rounds of electric field and short-circuit force simulations, and uses high mechanical strength conductors and special end fixation. The body structure is compact, and the pressing and positioning system can withstand long-distance transportation. The oil tank and accessories meet the requirements of full vacuum treatment, and the assembly process strictly follows the drying time control to ensure insulation performance. The product is suitable for large substations and hub projects.

Product Parameters

Rated Capacity (kVA)	Voltage Combination			Connection Group Symbol	No-load Loss (kW)	Load Loss (kW) (75℃)	No-load Current (%)	Short-circuit Impedance (%)
Rated Capacity (kVA)	High Voltage (kV)	High Voltage (kV)%	Low Voltage kV	Connection Group Symbol	22	Load Loss (kW) (75℃)	No-load Current (%)	Short-circuit Impedance (%)
3150	35~ 38.5	±2x2.5% 土5%	3.15 6.3 10.5	Yd11	1.7	20.7	0.45	7.0
4000					2.0	24.6	0.45
5000					2.4	28.2	0.35
6300					2.9	31.5	0.35	8.0
8000		±2x2.5%	3.15 3.3 6.3 6.6 10.5	YNd11	4.0	34.6	0.30
10000					4.8	40.8	0.30
12500					5.5	48.4	0.30
16000					6.7	59.2	0.25
20000					7.9	71.6	0.25
25000					9.4	84.6	0.28	10.0
31500					11.1	100.8	0.28	10.0

Rated Capacity kV-A	Voltage Combination		Connection Group Symbol	No-load Loss (kW)	Load Loss (kW)	No-load Current (%)	Short-circuit Impedance (%)
Rated Capacity kV-A	High Voltage and Tap Range (kV)	Low Voltage	Connection Group Symbol	22	Load Loss (kW)	No-load Current (%)	Short-circuit Impedance (%)
6300	110±2x2.5% 115±2x2.5% 121±2x2.5%	6.3 6.6 10.5	YNd11	4.1	32.0	0.62	10.5
8000				4.9	38.0	0.62
10000				5.8	45.0	0.58
12500				6.8	53.0	0.58
16000				8.3	65.7	0.54
20000				9.7	79.0	0.54
25000				11.4	94.0	0.50
31500				13.5	111	0.48
40000				16.2	133	0.45
50000				19.4	158	0.42
63000				22.9	187	0.38
75000		13.8 15.75 18 21		26.0	212	0.33	12~14
90000				29.9	245	0.30
120000				37.3	303	0.27
150000				44.1	359	0.24
180000				49.5	411	0.20
Note 1: For step-up transformers, a tapless structure is recommended. Taps can be provided if required by operation. Note 2: When the annual average load factor of the transformer is between 42% and 46%, the maximum operating efficiency can be achieved using the loss values in the table.

Rated Capacity kV-A	Voltage Combination		Connection Group Symbol	No-load Loss (kW)	Load Loss (kW)	No-load Current (%)	Short-circuit Impedance (%)
Rated Capacity kV-A	High Voltage and Tap Range (kV)	Low Voltage	Connection Group Symbol	22	Load Loss (kW)	No-load Current (%)	Short-circuit Impedance (%)
31500	220±2×2.5% 242±2×2.5%	6.3 6.6 10.5	YNd11	15	115	0.56	12～14
40000				18	134	0.56
50000				21	161	0.52
63000				25	188	0.52
75000		10.5 13.8		29	213	0.48
90000				34	246	0.44
120000				41	304	0.44
150000		10.5、13.8 11、13.8 15.75 18、20		49	360	0.40
160000				51	378	0.39
180000				56	413	0.36
240000				70	484	0.33
300000		15.75 18 20		83	577	0.30
360000				95	662	0.30
370000				97	675	0.30
400000				103	716	0.28
420000				106	742	0.28
Note 1: Transformers with a rated capacity of less than 31500 kVA and those with other voltage combinations can also be provided upon request.Note 2: Transformers with a low voltage of 35 kV and 38.5 kV can also be provided upon request.

Product Introduction

Transformer Features

Our company manufactures transformers with the following characteristics: low loss, low noise, low partial discharge, no leakage, and strong short-circuit resistance. They do not require core lifting during on-site installation, and the transformer body is maintenance-free for 20 years. Below are the main features of transformers with voltage ratings below 110 kV in terms of structure and process.

Core Section

1.Core Material and Structure

High-performance grain-oriented silicon steel sheets are selected for the core. The core adopts a fully oblique multi-stage step joint structure, and the non-overlapping yoke process is used, which helps reduce no-load losses and noise.

2.Core Assembly

The core column and yoke are bound using high-strength resin mesh banding materials, mechanically bundled and cured. This ensures good core perpendicularity.

3.Mechanical Strength

The core structure has high mechanical strength. Notably, the frame structure made of large laminated clamp plates effectively clamps the core together, ensuring sufficient short-circuit mechanical strength. This design also meets the requirement for no core lifting during transportation and on-site installation.

4.Core Connectors

All core structural components are rounded to avoid sharp edges. In areas with high field strength where lead wires pass through, special insulation sheaths are added to reduce partial discharge.

5.Electrical Reliability

All core component connections are left unpainted to ensure reliable electrical connection and prevent localized electrical potential. Both the clamps and core are grounded separately.

Coil Section

1.Electrical Structure Design

Electrical structural parameters are calculated using analysis software.

2.Voltage Distribution

All coils are analyzed using wave process calculation software for voltage distribution and repeatedly adjusted to ensure a reasonable gradient distribution. The electrical field strength of the transformer body is also verified to ensure optimal main longitudinal insulation parameters and electrical strength.

3.Coil Insulation

All coils are wound on hard insulation tubes that have been pre-dried and impregnated with oil for pre-stabilization. The outer coils are supported with external support strips, and additional auxiliary support strips are added inside the inner coils to improve short-circuit resistance.

4.Short-Circuit Resistance

Based on short-circuit mechanical force calculations, self-adhesive transposed conductors or semi-rigid conductors are used for the inner coils, which have extremely high mechanical strength and meet short-circuit resistance requirements.

5.Enhanced Short-Circuit Strength

All coil terminals and end parts are bound with high-shrink polyester heat-shrink tubes and heat-shrink tapes to increase short-circuit resistance.

6.Coil Structure and Cooling

The inner and outer coil spacers are designed based on calculated values and may differ, ensuring a rational distribution. The coils are equipped with a guided cooling structure for optimal heat dissipation. In addition, heat-pressed insulation molded parts replace traditional cardboard spacer strips at the coil transposition points. The oil gap spacer blocks are rounded and pre-impregnated, improving axial short-circuit resistance.

7.Vacuum Drying and Assembly

After vacuum drying, individual coils are assembled in phase. The main oil gap spacers between the coils are fixed using special positioning plates. After vacuum drying the coils, their heights are checked and adjusted to ensure that coils in the same phase are under consistent load, improving short-circuit strength.

Transformer Body Section

1.Body Structure

The transformer body adopts a single-phase structure. The body press plates are made of laminated insulation board or laminated wood, which have sufficient short-circuit impact resistance.

2.Compression Structure

The compression structure of the body uses laminated insulation board press blocks instead of traditional nails, increasing the cross-sectional area of the compression blocks and reducing the compression force. This structure uses hydraulic devices to set a pre-compression force during assembly after the drying process.

3.Lead Supports

All lead supports are made of high-density laminated wood and form a frame structure. Some lead supports are formed using laminated insulation paperboard, which increases both mechanical and electrical strength. All supports use laminated wood insulation nuts with a special anti-loosening structure.

Oil Tank and Assembly Section

1.Vacuum Oil Tank

All transformers rated for 110 kV and below use a fully vacuum-sealed oil tank with a barrel-shaped structure. The upper and lower sections of the oil tank can be connected either by bolts or welded to meet the requirement for no core lifting and maintenance-free operation. The inside of the oil tank is fully polished and rounded.

2.Oil Conservator

All transformer oil conservators can withstand full vacuum strength and are equipped with airbags and pointer-type oil level indicators. After all transformer accessories are assembled, the conservator can be evacuated to a full vacuum before oil injection, effectively preventing the formation of bubbles inside the insulation components and transformer, reducing partial discharge.

3.Sealing Structure

The sealing surfaces of the transformer, including bushings, adopt a hard connection structure with limit grooves, and high-quality sealing components are used with sealing adhesives to ensure no leakage.

4.Positioning and Reliability

The transformer is equipped with a special upper and lower positioning structure, which ensures reliability, resistance to transportation shocks, and meets the requirement for no core lifting during installation.

5.Secondary Wiring

Secondary wiring is arranged according to the user’s requirements, using stainless steel cable trays or armored cables, and all wiring is connected to terminal boxes to facilitate user installation.

6.Advanced Assembly Process

The transformer body undergoes an equivalent exposure time control from drying to vacuum oil impregnation, ensuring continuous high-vacuum degassing during the assembly of all accessories. This effectively controls moisture absorption in insulation components.

Quality Control

Our company’s entire transformer production process follows an advanced process management system for quality control. Processes such as wire production, insulation material fabrication, coil manufacturing, and body assembly are all carried out in dust-free work zones, with the air cleanliness controlled to 3 μg/cm²·day or below.

Company Profile

Changzhou Pacific Electric Equipment (Group) Co., Ltd. Is a high-tech enterprise in China dedicated to green and intelligent power transmission and distribution technologies. The company was established in 1989 and formed a group in 1997, with a registered capital of 130 million yuan. It has always integrated the concept of sustainable development into its products and services.
The company's base is located in a modern 240,000-square-meter industrial park. The building area is 120,000 square meters, with fixed assets amounting to 500 million yuan. The company produces over 20,000 sets of energy-saving and environmentally-friendly electrical equipment annually.

Our core strength lies in green innovation and sustainable development:

The driver of industry green development: As a leading member of the China Electrical Equipment Industry Association and its specialized branches, he actively participated in the formulation of energy conservation and environmental protection standards and advocated for the green transformation of the industry.

Green Product Ecosystem: Offers a complete range of products including energy-efficient transformers, environmentally friendly switchgear, intelligent power distribution systems, and solutions for integrating new energy sources, helping customers build a green power system.

Green Technology Innovation Engine: The company is a national-level high-tech enterprise. Its research and development focuses include equipment energy-saving technology, application of environmental-friendly materials, and intelligent energy efficiency management, aiming to reduce the carbon footprint of the power system through technological innovation.

Green manufacturing practice: Implementing clean production and efficient utilization of resources. Key processes are carried out in controlled environments to reduce pollution. Products undergo strict environmental protection inspections to ensure compliance with international and domestic environmental standards.

Successful green application cases: The company's energy-saving and environmental protection products have been widely applied in projects such as smart grids, green buildings, clean energy, and eco-industrial parks, providing strong support for customers to achieve their energy conservation and emission reduction goals.

Responsible Partner: Adhering to the values of "professionalism, integrity, cooperation, and innovation", we provide customers with green technology consulting and services throughout the entire lifecycle. We are committed to jointly promoting the sustainable development of the power industry with our clients.

Thanks to its continuous investment and successful implementation in green technologies, the company has become an important partner for customers in achieving their carbon reduction goals and sustainable development visions.