HVIL (High Voltage Interlock) is a safety feature that uses a low voltage circuit to monitor the integrity of the high voltage circuit, designed to protect those who may come into contact with the high voltage system of an electric vehicle.
The main electrical components in the electric vehicle (EV) high voltage interlock system are the HVIL connector and the MSD (Manual Service Disconnect) connector.
Metabee HVIL connectors family features a wide temperature and wire range and multiple keying options for many electric vehicle applications. Assembly is simplified with a lever assist for low insertion force.
Metabee HVIL connectors provide a robust design that optimizes package size and plug and header selections to create multiple wire harness assembly routing options. The touch-proof HVIL connectors and headers are engineered with 90-degree and 180-degree plugs and feature an integrated internal HVIL function and EMI shielding.
|Mfr Part #||NI1-1-H036-3AYN-C05|
|Number of Positions||3|
|Mounting Type||Panel Mount|
|Mounting Feature||Four Flange|
|Body Material||Zinc Alloy|
|Contact Material||Copper Alloy|
|Temperature Range||-40°C~ +125°C|
|Flammability Rating||UL94 V-0|
|Feature||Integrated internal HVIL|
Options rated for 800V and 1,500V
250-amp maximum current rating
IP rating: Mated: IP67, IP6K9K, Unmated: IP2xb
SHITU offers a multiple set of automotive HVIL system solutions with high voltage connectors from 1-6 poles. SHITU’s high voltage connectors are engineered with 90-degree and 180-degree plugs and feature an integrated internal HVIL function and EMI shielding.
The high-voltage connectors are made of PA66 insulation and have passed a high temperature test of 128°C for 1008 hours. Assembly is simplified with a lever assist for low insertion force.
The core technology for any power connection system is the contact. SHITU uses advanced contacts designed to maximize power transfer while minimizing space requirements and minimizing the length and diameter required for a given current while maintaining a good temperature response.