Toshiba HV6CS-MU operation manual Storage

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2.3 Storage

Use the following procedures if the VCB will not be operated for a long period of time after it has been installed, or if it must be stored for a long period of time prior to installation. Be sure to observe the precautions for storage and installation locations (see page 5).

(1)When storing the unit, cover it with a dust cover.

(2)Avoid locations subject to high humidity or exposed to direct sunlight.

(3)Inspect the unit periodically and make sure there are no problems such as condensation, moisture absorption, rust, corrosion or insects inside the equipment. If such problems are discovered, inspect the equipment carefully and repair it before it is operated.

WARNING

To prevent electric shock or other injury, do not use the unit when a problem has been discovered during an inspection of that unit.

CAUTION

To prevent injury or damage to the equipment, make sure the unit is standing straight up. NEVER lay it on its side or place it upside-down.

(4)When the equipment has been stored or has been idle for a long period of time, do not install or begin operating the unit immediately. Perform the procedures listed in sections 7.3 and 7.4 and the withstand voltage test* for the control circuit to make sure there are no problems before installing or operating the unit.

*The withstand voltage on control circuits

The withstand voltage test for motor spring operation type circuit breaker shall be performed in charged condition.

The power frequency withstand voltage on control circuits except charging motor is 2000V AC, since the withstand voltage for charging motor is 1500V AC.

The motor circuit shall be disconnected before withstand voltage test on control circuits. (Example: The connector plug (white) on upper-center of control board should be disconnected (pull out) after removing the front cover of circuit breaker. This will make the motor circuit disconnect

Note: The connector plug and front cover must be returned to proper position after withstand voltage test.

CONNECTOR PLUG (WHITE)

CONTROL

BOARD (UNIT)

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Contents HV6CS Vacuum Circuit Breakers Fixed Type 7.2kV Voltage Class Page Important Notice About This Manual Contacting TIC’s Customer Support Center Table of Contents General Safety Information Safety Alert SymbolEquipment Warning Labels Equipment Inspection Connecting and disconnecting the main circuit Operating the VCBInstallation location During UseSpecial environmental conditions Applicable standards pertaining to switching surges Part Names From Receipt to Storage Receipt and UnpackingTransport Wrong Incorrect Method of TransportationTransportation Manual handling Storage Installation Mounting the VCBMounting in the panel Mounting Directly onto the Floor Screw Tightening Tightening torque Nominal Torque DiaPage Main Circuit Terminal Connections Pass the cable or conductor through the insulating cylinderGround Terminal Connections Control Circuit Cable ConnectionsClosing the Circuit OperationManual Operation For Motorized Spring-operated VCBsCharging Handle Closed Lever Opening the Circuit Electrical Operation Control Circuit Motorized OperationPlug Installed in UV Trip Device Undervoltage TripMaintenance/Inspections Maintenance RecordDuring Maintenance/Inspections Types of Maintenance and Inspection WorkInspection Frequency Periodic Inspection Checkpoints Type of inspection Inspection frequencyVacuum Check Location Inspection Criteria Disposition Remarks MethodPrecautions Test Procedure Dielectric Breakdown Characteristics Page Toshiba

HV6CS-MU specifications

The Toshiba HV6CS-MU is a high-performance semiconductor device, primarily designed for automotive applications, particularly in battery management systems and electric vehicles. This versatile chip is part of Toshiba's HV series, known for its reliability, robustness, and efficiency in handling high voltage operations.

One of the standout features of the HV6CS-MU is its ability to operate at high voltages, making it suitable for demanding environments where traditional components may falter. It supports voltages up to 600V, which is essential for managing the power requirements of electric and hybrid vehicles. This high voltage capability allows for efficient energy management in various systems, from power inverters to energy storage units.

Additionally, the HV6CS-MU leverages Toshiba's proprietary technologies, including advanced gate drive and protection circuits. These technologies ensure that the device operates safely and reliably under various conditions. The built-in protection features help guard against over-voltage, over-current, and thermal problems, which are critical for maintaining system integrity and longevity.

Another compelling aspect of the HV6CS-MU is its efficiency. With low on-resistance and fast switching times, it minimizes power loss during operation. This efficiency translates not only to improved performance but also to extended battery life in electric vehicles. The ability to conserve energy is paramount in today's automotive industry, where sustainability and energy efficiency are increasingly important.

Furthermore, the HV6CS-MU is designed with a robust thermal management system. It can operate at elevated temperatures without compromising performance, making it suitable for various automotive environments. This feature is particularly vital in electric vehicles, where components are often subjected to significant heat during operation.

In terms of packaging, the HV6CS-MU comes in a compact, integrated format, allowing for ease of installation within various electronic assemblies. Its small footprint makes it ideal for space-constrained applications, providing engineers with more design flexibility.

In summary, the Toshiba HV6CS-MU is a state-of-the-art semiconductor device that embodies advanced technology, high efficiency, and robust performance characteristics. Its high voltage operation, integrated protection features, and efficient energy management make it a pivotal component in modern automotive designs, particularly in the realm of electric and hybrid vehicles. As the industry continues to evolve towards electrification, devices like the HV6CS-MU will play an essential role in shaping the future of automotive technology.
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