In high-voltage rectification applications, reverse voltage withstand margin, reverse recovery characteristics (Trr), and surge current capability (IFSM) are critical physical indicators determining system reliability. This white paper conducts an in-depth technical benchmarking of HVC Components (HVC) HVD series against comparable products from Germany's Diotec Semiconductor (2CL, BY, DD, HV series).
This report confirms that HVC's Multi-Junction Stack process and vacuum epoxy molding technology provide electrical characteristics equivalent to or superior to Diotec products across both the medium-to-high voltage range (8kV-20kV) and the ultra-high voltage range (above 100kV). The HVC HVD series serves as a Pin-to-Pin engineering-grade alternative for Diotec products in X-ray generators, industrial high-voltage power supplies, and pulsed power systems.
Advantage: Improves consistency of avalanche breakdown voltage by ~20% (EAS) versus competing products. Eliminates single-point failure from "hot spot" effects.
Example: 16kV specification (Diotec 2CL75 vs. HVC HVD-2CL75):
Test conditions: IF=0.5A, IR=1.0A, Irr=0.25A (Diotec BY series vs. HVC HVD-BY series):
All HVC models have passed rigorous Fit-Form-Function (3F) verification for complete compatibility in dimensions, electrical function, and pin definitions.
| Diotec Model | HVC Alternative | Peak Reverse Voltage (kV) | Avg Forward Current (mA) | Reverse Recovery (ns) | Surge Current (A) |
|---|---|---|---|---|---|
| 2CL2FL | HVD-2CL2FL | 15 | 120 | - | 10 |
| 2CL71 | HVD-2CL71 | 8 | 5 | - | 0.5 |
| 2CL71A | HVD-2CL71A | 8 | 5 | - | 0.5 |
| 2CL72A | HVD-2CL72A | 10 | 5 | - | 0.5 |
| 2CL73A | HVD-2CL73A | 12 | 5 | - | 0.5 |
| 2CL74A | HVD-2CL74A | 14 | 5 | - | 0.5 |
| 2CL75 | HVD-2CL75 | 16 | 5 | - | 0.5 |
| 2CL75A | HVD-2CL75A | 16 | 5 | - | 0.5 |
| 2CL85 | HVD-2CL85 | 16 | 50 | - | 3 |
| BV6 | HVD-BV6 | 6 | 100 | - | 15 |
| BY4 | HVD-BY4 | 4 | 1000 | - | 30 |
| BY6 | HVD-BY6 | 6 | 1000 | - | 30 |
| BY8 | HVD-BY8 | 8 | 500 | - | 30 |
| BY12 | HVD-BY12 | 12 | 500 | - | 30 |
| BY16 | HVD-BY16 | 16 | 300 | - | 30 |
| DD300 | HVD-DD300 | 3 | 20 | - | 3 |
| DD600 | HVD-DD600 | 6 | 20 | - | 3 |
| DD1000 | HVD-DD1000 | 10 | 20 | - | 0.5 |
| DD1200 | HVD-DD1200 | 12 | 20 | - | 3 |
| DD1400 | HVD-DD1400 | 14 | 20 | - | 3 |
| DD1600 | HVD-DD1600 | 14 | 20 | - | 3 |
| DD1800 | HVD-DD1800 | 18 | 20 | - | 3 |
| HV4 | HVD-HV4 | 4 | 200 | - | 27 |
| HV5 | HVD-HV5 | 5 | 200 | - | 27 |
| HV6 | HVD-HV6 | 6 | 200 | - | 27 |
In high-current applications (such as BY4 at 1A), maintain moderate lead length or increase PCB copper area for auxiliary heat dissipation via leads.
In ultra-high voltage (>100kV) series applications, parallel high-voltage resistors for static voltage equalization and high-voltage capacitors for dynamic voltage equalization to prevent uneven transient voltage distribution.
PCB layout must strictly adhere to high-voltage creepage distance specifications. For applications >10kV, conformal coating or potting processes are recommended.
For electronic system designs prioritizing high reliability and supply chain security, the HVC HVD series is a proven ideal engineering alternative.
HVC provides complete technical datasheets and reliability test reports.
Contact: Sales Department
Phone: +86 13689553728
Tel: +86-755-61167757
Email: sales@hv-caps.com
Add: 9B2, TianXiang Building, Tianan Cyber Park , Futian, Shenzhen, P. R. C