SERVICES

Next-Generation Renewable Energy Business

Ultra-High-Efficiency, Low-Environmental-Impact Energy Circulation System

This project aims to research, develop, and implement an ultra-clean power generation circulation system that will serve as a core component of next-generation energy infrastructure.

In recent years, global electricity demand has been expanding exponentially due to advances in AI and the rapid increase in data centers. Conventional thermal, nuclear, and renewable energy sources each face challenges such as energy conversion losses, environmental impact, and supply stability, making fundamental technological innovation essential for sustainable power supply.

This system is an innovative power generation system developed to address these challenges, simultaneously achieving high efficiency, low loss, and low environmental impact.

Overview

Core Technologies of the Business

This system adopts a linear power generation method (magnetic levitation type) that applies superconducting technology and magnetic force control, without relying on conventional rotational mechanisms.

■Key Features

Minimization of mechanical friction, significantly reducing energy loss
Direct power generation, achieving higher efficiency through simplification of the conversion process
Stable power supply through suppression of voltage drops and power factor losses
Optimally suited for AI equipment, semiconductors, and data centers requiring high-precision power sources

Application and Deployment Areas

This system enables deployment across a wide range of industrial sectors through an integrated design that combines power generation and motive power.

■Mobility Sector

Electrification support for EVs (from large trucks to small vehicles)
Integration as a next-generation power unit

■Industrial and Infrastructure Sector

Power supply for ships, construction machinery, and agricultural machinery
Industrial applications such as pumping systems and machine tools

■Energy Supply Sector

Distributed power sources (small-scale power generation)
Construction of large-scale power plants and microgrids
Dedicated power infrastructure for data centers

Technical Advantages

This system has the following advantages compared to conventional technologies:

Clean design that does not use fossil fuels
Low environmental impact structure with suppressed heat generation and emissions
Improved maintainability through reduction of mechanical components
Simplification of auxiliary equipment such as transmissions and cooling systems
High versatility enabled by a simple control structure

Note: Performance may vary depending on the deployment environment and specifications.

Power Generation Scale

Flexible scaling is possible according to application requirements.

Small-scale units: 10 kW class
Medium-scale systems: Several MW class
Large-scale plants: 100 MW or more (expandable through modular configuration)

Social Significance and Market Value

This system is positioned not merely as a power generation device, but as an infrastructure technology that transforms the very nature of energy supply.

■Anticipated Social Value

Contribution to the realization of a carbon-neutral society
Development of energy self-sufficient communities (distributed power sources)
Optimization of electricity costs and stable power supply
Acceleration of infrastructure development in emerging economies

Currently, this system is attracting interest from government agencies, industry partners, and investors in various countries, and is expected to serve as a strategic solution in the next-generation energy market.

Future Development

Joint development and technology partnerships in global markets and with strategic partners
Development of integrated energy × digital infrastructure