Industry news

I work where meters spin and bills bite. On real sites—clinics, depots, factory lines—I’ve seen storage either pay for itself or sit as a stranded box. With GEYA hardware in the loop and an Energy Storage System tuned to each site’s rhythm, we treat storage like a teammate: it pockets midday solar instead of dumping it, trims the ugly peaks that trigger tariffs and trips, and steps in so fast during a fault that screens don’t even flicker. That’s the standard I hold to on every deployment.

I spend most of my week immersed in factories running variable frequency drives, uninterruptible power supplies and rapid charging equipment, so I care less about buzzwords and more about solutions that stand up to the Monday morning test.

The Static Var Generator (SVG) is a state-of-the-art power electronic device designed to improve power quality in electrical distribution systems. It functions primarily by dynamically regulating reactive power, maintaining voltage stability, and mitigating harmonic distortion. In an era where renewable energy integration and industrial automation are expanding rapidly, ensuring stable and efficient power delivery is crucial. This article explores the operational principles, advantages, technical specifications, and emerging trends of Static Var Generators while addressing frequently asked questions to help engineers, energy managers, and industrial planners make informed decisions.

In today’s rapidly evolving industrial and commercial environments, power quality has become a critical factor influencing productivity, equipment performance, and operational costs. With the increasing use of non-linear loads like variable frequency drives (VFDs), data servers, robotics, and LED lighting systems, harmonic distortion in power networks has become a common challenge. One of the most effective solutions to mitigate harmonics and improve energy efficiency is the Rack Mount Active Harmonic Filter (AHF).

In an era where industries, commercial buildings, and critical infrastructure rely heavily on sensitive electronic equipment, maintaining clean and stable power has become a non-negotiable priority. Harmonics—distortions in the electrical current caused by non-linear loads like variable frequency drives, computers, and LED lighting—can lead to equipment failures, energy waste, and increased operational costs. Active Harmonic Filters (AHFs) have emerged as a cutting-edge solution to mitigate these issues, ensuring power systems operate efficiently and reliably. This guide explores why AHFs are essential for modern power systems, their working principles, detailed specifications of our advanced filters, and answers to common questions to highlight their transformative impact.

Home solar panels have become a popular choice for upgrading the household energy structure due to their energy conversion efficiency and long-term economic performance. They can convert sunlight into electrical energy, which not only reduces dependence on traditional power grids and reduces household electricity costs, but also conforms to the concept of environmental protection. Its improvement in installation convenience and technical maturity allows ordinary families to easily embrace clean energy. ​