Application: | Power, Electronic, Rectifier |
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Phase: | Three |
Core: | Amorphous Alloy Transformer |
Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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Payment Method: | |
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Initial Payment Full Payment |
Currency: | US$ |
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Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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1. Safety and Reliability: The transformer is constructed using non-toxic, flame-retardant epoxy resin, offering high mechanical strength, flame resistance, fire prevention, and environmental friendliness.
2. Convenient Installation: Dry-type rectifier transformers are delivered as complete units, allowing for immediate installation and efficient operation.
3. High Overload Capacity: The transformer's insulation is rated at class H , with a heat resistance temperature reaching 180°C. It can handle maximum overloads of up to 200%.
4. Low Noise: Noise levels are reduced by 3-5 decibels compared to national standards.
5. Cost Savings: Dry-type rectifier transformers can be installed in conjunction with electrical equipment such as rectifiers, eliminating the need for a separately designed distribution room. This saves space and reduces initial investments.
6. Diverse Range: Our product offerings are comprehensive, covering specialized transformers in various fields, including rectifier transformers, electric furnace transformers, and variable frequency transformers.
7. Tailor-Made Solutions: We can accommodate specific customer requirements, offering flexible design and rapid responses.
8. Authoritative Certification: Our products have received authoritative certification from the National Electrical Product Quality Supervision and Inspection Center.
24-Pulse Rectifier Dry-Type Transformer |
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Model |
Capacity(KVA) |
Rated Voltage(KV) |
Tapping Range |
Connection Section |
Short Circuit Impedance |
Efficiency |
Weight(kg) |
Gauge(mm) |
|
Net Side |
Valve Side |
||||||||
ZBSCB10 |
200 |
10 |
0.4 |
2*2.5% |
Dyn11 |
4.0 |
≥0.97 |
1250 |
550 x 550 |
ZBSCB10 |
250 |
4.0 |
≥0.97 |
1430 |
550 x 550 |
||||
ZBSCB10 |
315 |
4.0 |
≥0.97 |
1570 |
660 x 660 |
||||
ZBSCB10 |
400 |
4.0 |
≥0.98 |
1750 |
660 x 660 |
||||
ZBSCB10 |
500 |
4.0 |
≥0.98 |
1970 |
820 x 820 |
||||
ZBSCB10 |
630 |
6.0 |
≥0.98 |
2250 |
820 x 820 |
||||
ZBSCB10 |
800 |
6.0 |
≥0.98 |
2590 |
820 x 820 |
||||
ZBSCB10 |
1000 |
6.0 |
≥0.98 |
2940 |
820 x 820 |
||||
ZBSCB10 |
1250 |
6.0 |
≥0.98 |
3420 |
820 x 820 |
||||
ZBSCB10 |
1600 |
6.0 |
≥0.98 |
3830 |
820 x 820 |
||||
ZBSCB10 |
2000 |
6.0 |
≥0.99 |
4500 |
820 x 820 |
||||
ZBSCB10 |
2500 |
6.0 |
≥0.99 |
5350 |
820 x 820 |
||||
ZBSCB10 |
500 |
35 |
6.0 |
≥0.98 |
2680 |
820 x 820 |
|||
ZBSCB10 |
630 |
6.0 |
≥0.98 |
3300 |
820 x 820 |
||||
ZBSCB10 |
800 |
6.0 |
≥0.98 |
3810 |
820 x 820 |
||||
ZBSCB10 |
1000 |
6.0 |
≥0.98 |
4650 |
1070 x 1070 |
||||
ZBSCB10 |
1250 |
6.0 |
≥0.98 |
5250 |
1070 x 1070 |
||||
ZBSCB10 |
1600 |
6.0 |
≥0.98 |
5750 |
1070 x 1070 |
||||
ZBSCB10 |
2000 |
6.0 |
≥0.99 |
6380 |
1070 x 1070 |
||||
ZBSCB10 |
2500 |
6.0 |
≥0.99 |
7390 |
1070 x 1070 |
1. Reliability of Insulation Technology
Our research spans from initial two-dimensional electric field simulations, three-dimensional electric field measurements, and impact characteristic measurements to later-stage theoretical analysis and simulated experiments on the main insulation, longitudinal insulation, end insulation, insulation of leads, and coil withstand voltage characteristics of transformers. Through years of verification using various methods, we ensure the reliability of transformer insulation.
2. Calculation of leakage magnetic field and reduction of stray loss
Dedicate specialized efforts to calculating and measuring transformer leakage magnetic fields. The research includes shielding structures for leakage magnetic fields, calculations for transformer dynamics and thermal stability, and improvements in transformer dynamic and thermal stability to guarantee accurate calculations and reduced stray losses, thereby enhancing transformer dynamic stability.
3. Precise Analysis of Coil Temperature Fields
Collaborating with numerous domestic universities, we jointly developed programs for calculating coil temperature fields. These programs calculate loss distribution in coils, including resistive losses, eddy current losses in different directions, and circulating losses between parallel conductors, as well as flow field cooling conditions. This enables the accurate calculation of coil temperature distribution and hotspot temperature rises, allowing us to take measures to effectively control hotspot temperature rises that impact transformer lifespan.
4. Reducing Local Discharge in Transformers
Electric field strengths at various locations have undergone numerical analysis during the design phase and have been strictly controlled. Additionally, compliance with manufacturing quality, the reliability of processing methods, and the reasonableness of operating techniques effectively control local discharges in transformers.
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