General Specifications, Input | Emerson 510 VDC instruction

LIEBERT FS FLYWHEEL ENERGY STORAGE SYSTEM - 190 KW, 10 SECONDS

General Specifications

INPUT

	Voltage	520VDC, Nominal (Recharge)

	Voltage Range	480 to 540VDC

	ENVIRONMENTAL
	Operating	-4°F to 122°F
	Temperature	(-20°C to 50°C)
	Non-Operating	-4°F to 176°F
	Temperature	(-20°C to 80°C)
	Relative Humidity	5-95% non-condensing

	Operating Altitude	Up to 9,842 ft. (3,000m)

	Acoustical Noise	45 dBA in Ready Mode, measured
	Acoustical Noise	3.3 ft. (1m) from the unit
		3.3 ft. (1m) from the unit

OUTPUT

Voltage	510VDC, Nominal (Discharge)

Voltage Range	480 to 540VDC

STANDARDS

•UL listed to the following Standards:

•UL 1248, Standard for Engine/Generator Assemblies

•UL 508, Standard for Industrial Control Equipment

•UL 1004, Standard for Electric Motors

•CSA C22.2 No. 14-95, Industrial Control Equipment

•Meets current global requirements for safe, high-performance operation.

•Carbon Fiber Flywheel

•5-Axis Active Magnetic Levitation System

•Integrated, Low-Loss Vacuum System

•Synchronous Reluctance Motor-Generator

•Integrated Safety System

•5-Year Parts Warranty

The Liebert FS is a technologically advanced DC energy storage system that utilizes a rotating mass as a means for storage. Over 10 years and millions of dollars of development have resulted in a safe, efficient product that can be used in place of or in parallel with batteries. Stored energy is available immediately and released upon demand—up to 190kW is available for up to 10 seconds and can be used to:

•Ride through short power outages without the need to go to battery or generator

•Provide enough time to place generators on line during prolonged blackouts without the need for batteries

•Parallel with battery strings to provide extended backup time, battery life and reliability

The Liebert FS consists of several modules. The Flywheel Module contains technologically advanced components. Supported by an active magnetic levitation system (Magnetic Levitation Module), the carbon composite flywheel rotates within two containment vessels that make up a low-loss and extremely safe operating environment. The Power Conversion Module is a bi-directional high-frequency converter that provides a regulated output to the DC bus during discharge and becomes a source for a variable frequency/voltage to drive (spin) the flywheel during recharge. The Power Conversion Module Controller monitors and keeps all components within safe operating limits. FS units may be paralleled for additional power or time.

A circuit breaker for disconnecting means (manually or automatic) is standard in the Liebert FS. Also standard is an LCD user interface that displays the system’s operating status. Soft keys on the user interface provide control of the unit. Additional monitoring and control options are available.

With its quiet operation, relatively small dimensions and weight of 1300 lb. (590 kg), the Liebert FS may be installed in any typical electrical equipment environment. Installation is simple—power and control wiring are the same as those found in Liebert Battery Cabinet installations.

510 VDC specifications

The Emerson 510 VDC is a highly versatile and advanced digital control system designed for use in various industrial applications, particularly in the oil and gas, power generation, and process manufacturing sectors. This system exemplifies Emerson’s commitment to increasing efficiency, safety, and performance through innovative technologies and user-friendly features.

One of the main features of the Emerson 510 VDC is its ability to handle high voltage direct current (HVDC) applications. This is crucial for industries that require reliable energy transmission over long distances with minimal losses. The system supports advanced control algorithms that optimize the performance of HVDC links, ensuring stability and improved power quality.

The Emerson 510 VDC employs state-of-the-art digital signal processing technologies, which enable rapid response times and precise control of electrical systems. This allows for real-time monitoring and adjustments, ensuring that operations run smoothly and safely. With built-in redundancy features, the system enhances reliability, mitigating risks associated with equipment failures.

Another notable characteristic of the 510 VDC is its modular architecture. This enables users to easily configure and expand the system according to specific operational needs. Whether integrating new components or upgrading existing ones, the modular design simplifies maintenance and scalability, accommodating future growth without significant downtime.

Furthermore, the Emerson 510 VDC incorporates advanced communication protocols that facilitate seamless integration with other industrial systems and devices. This interoperability is critical for achieving a holistic view of operations and improving overall system performance. Additionally, the user interface is designed to be intuitive, providing operators with easy access to critical data and control mechanisms.

Safety is a prime consideration in the design of the Emerson 510 VDC. The system is equipped with comprehensive diagnostics and protective features that safeguard equipment and personnel. It adheres to strict industry standards, ensuring compliance and enhancing operational reliability.

In summary, the Emerson 510 VDC stands out for its advanced HVDC capabilities, high-performance digital processing, modular design, and enhanced safety features. These characteristics make it a vital component for industries looking to improve electric power efficiency, reliability, and management in an ever-evolving technological landscape. As industries continue to grapple with energy challenges, the Emerson 510 VDC offers a robust and flexible solution for modern energy demands.