Executive Summary
As Murata (Japan) discontinues its DHS series and the global high-voltage component supply chain restructures, the high-voltage capacitor market is undergoing a profound reshuffle. For a long time, the American brand HVCA (Dean Technology) dominated the market with its brand halo. However, its "global procurement + private labeling" trading model has led to persistent issues such as a low technical ceiling (difficulty exceeding 50kV), long lead times (16-24 weeks), and inflated prices.
This manual, based on HVC Capacitor's source manufacturing strength, explains how to achieve a comprehensive upgrade and replacement of HVCA's NX series (ultra-high voltage) and JX series (custom large capacity) screw-terminal capacitors using internal dual-chip stacking technology (100kV+), solid copper terminal craftsmanship, and true N4700 dielectric. This is not just a brand change; it is a dual upgrade for both equipment performance and supply chain security.
Before starting the selection and replacement process, engineers and purchasing managers must recognize an industry fact: the HVCA capacitors you purchase may not be manufactured in the United States.
As a typical brand operator, HVCA's core business model is "supply chain integration + private label sales." This model dictates that its product capabilities are strictly limited by the capabilities of its OEM network (primarily located in China).
HVC is a source manufacturer with full-process capabilities. We are not looking for OEM factories; we are the factory.
Comparison Conclusion: What HVCA cannot do, HVC can; what HVCA can do, HVC does more reliably.
Replacement is not merely about improving parameters from weak to strong; it's a comprehensive revolution in structure and craftsmanship.
In high-voltage, high-current applications, contact resistance and heat dissipation are crucial, and mechanical strength is vital for installation safety.
Risks: Iron has poor conductivity and is prone to rust; the silver paste layer has extremely weak torque resistance, leading to "stripped threads" or direct terminal detachment with even slight force (>2.5 Nm) during installation.
Advantages: Copper's conductivity is more than 5 times that of iron, offering excellent heat dissipation. Coupled with a unique mechanical anchoring process, HVC capacitors can withstand an installation torque of 4.5 Nm. Tests by GE Healthcare and Siemens confirm: HVC's terminals are more durable and fully compatible with modern production line power tool installations.
In the ultra-high voltage domain above 40kV, single ceramic block solutions have reached their physical limits.
Principle: The voltage stress is evenly distributed across two internally series-connected chips, halving the voltage borne by each chip and multiplying the safety factor.
Achievement: This enables HVC to mass-produce "monster-grade" specifications like 50kV 8000pF, a product type that simply does not exist in HVCA's catalog.
This section is the core of the manual, focusing on HVCA's two main high-end series: NX (Ultra-High Voltage Standard Type) and JX (Large Capacity Custom Type).
| HVCA (Dean Tech) Actual Model | HVC Recommended Replacement Model | Specification (Voltage/Capacitance) | HVC Upgrade Technical Points |
|---|---|---|---|
| NX5T3M202K40KV | HVCT8G-40KV-DL-202K | 40kV / 2000pF | N4700 (Class I) + Dual-Chip Technology. Withstand voltage margin increased by 50%, completely solving the breakdown pain point at 40kV. |
| NX5T3M102K40KV | HVCT8G-40KV-DL-102K | 40kV / 1000pF | Solid copper terminals, dissipation factor <0.2%, perfect replacement for high-frequency capacitors in laser equipment. |
| NX5T3M501K40KV | HVCT8G-40KV-DL-501K | 40kV / 500pF | Optimized for high-frequency pulses, 8°C lower temperature rise than HVCA, longer lifespan. |
| NX5T3M472K30KV | HVCT8G-30KV-DL-472K | 30kV / 4700pF | Pin-to-Pin Compatible. Medical-grade quality, 100% partial discharge (PD) tested before leaving the factory. |
| NX5T3M222K30KV | HVCT8G-30KV-DL-222K | 30kV / 2200pF | Optimized creepage distance design to prevent surface flashover in high-altitude or high-humidity environments. |
| HVCA (Dean Tech) Actual Model | HVC Recommended Replacement Model | Specification (Voltage/Capacitance) | HVC Upgrade Technical Points |
|---|---|---|---|
| JX5T3M802K10KV | HVCT8G-10KV-E-802K | 10kV / 8000pF | Y5T (Class II) material. Compared to the original T3M, it offers higher capacitance and a smoother temperature drift curve. |
| JX5T3M103K10KV | HVCT8G-10KV-E-103K | 10kV / 10000pF | Low ESR design, strong resistance to large current ripple, specifically designed for high-power supply filtering. |
| JX5T3M222K15KV | HVCT8G-15KV-E-222K | 15kV / 2200pF | Upgraded insulation encapsulation, passed dual 85 test (85℃/85% humidity). |
| JX5T3M472K20KV | HVCT8G-20KV-E-472K | 20kV / 4700pF | Solid copper terminals replace the original iron caps, fundamentally eliminating the risk of rust. |
Besides screw-terminal types, HVCA's disc capacitors also face lead time and RoHS compliance issues. HVC offers a full range of benchmarking solutions.
HVCA T3M / ZM → HVC N4700 (Class I):
Used for high-frequency resonance, medical imaging. HVC's N4700 has lower loss and higher insulation resistance.
HVCA Y5U / Y5P → HVC Y5T (Class II):
Used for voltage multiplication, filtering. HVC's Y5T balances capacitance and stability, and is the specified material for Siemens voltage multiplier circuits.
Why did GE, Siemens, and ABB ultimately choose HVC?
JX5T3M... or NX5T3M...) to HVC.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