Voltreum

Voltreum

The modern world runs entirely on electricity. An uninterrupted power supply is required for everything from heating systems and appliances in homes to large machinery and equipment in factories. However, the resilience and dependability of traditional centralized power grids have been called into question over time. Blackouts, power outages, aging infrastructure, and rising costs have compelled businesses to seek out better power generation and supply solutions. A solution that ensures constant supply relieves cost pressures, uses green energy sources, and provides some energy freedom. It comes as no surprise that the world is turning to microgrids as the next best solution to power issues.

Until recently, microgrids were mostly used in large industrial operations, college campuses, and military bases. Recent technological advancements and increased awareness of the benefits of microgrids have accelerated adoption rates. According to Navigant Research’s Microgrid Deployment Tracker, the total microgrid market is expected to grow to a capacity of 19888.8 MW in a market worth $39.4 billion by 2028.

 

What exactly is a microgrid?

A microgrid is a local power supply grid that serves only the communities, campuses, and industries that surround it. A microgrid is distinguished by its ability to operate autonomously while disconnected from the main power grid.

It is defined by three major factors.

It is localized — The power is generated locally using fossil fuels and renewable energy sources.
It is self-contained — The grid can function both with and without the central power grid. Simply put, when the main grid fails, a microgrid can operate in island mode, i.e., independently of the central grid.
It’s perceptive — A microgrid controller is a sophisticated software protocol that intelligently switches between multiple power sources and the central power supply and local grid. It can also buy or sell surplus energy based on fluctuating energy prices.

 

What distinguishes it from a traditional grid?

A conventional power grid and a microgrid have several distinct differences.

When defined, a traditional grid is an interconnected system of power generation and distribution components such as synchronous machines, transformers, transmission lines, and local substations. It is a highly centralized operation, with all power generated centrally and distributed across a vast region to millions of homes and industries. To put it simply, it is a large-scale power supply network that is heavily reliant on electromechanical infrastructure and human expertise.

Microgrids, on the other hand, are a highly distributed small-scale power supply network that can function both with and without a central power supply. It’s much smarter and can switch between connected and island modes as needed. While microgrids are not a new concept, newer ones use renewable energy sources such as wind and solar to reduce reliance on fossil fuels.

What are the main applications?

The traditional power supply’s centralized nature is its most serious flaw. Even if only one part of the grid fails, several regions lose power. This has happened several times, most notably during natural disasters. Because of their interconnectedness, several states frequently lose power supply at the same time. Microgrids can help with this.

Microgrids can be installed on campuses by organizations and communities looking to reduce their energy costs.

Microgrids can provide energy to organizations that require it 24 hours a day, seven days a week.

Installing microgrids with solar and wind capabilities can be extremely beneficial to communities that want to focus on sustainable energy production while reducing their carbon footprint.

Remote communities, campuses, and rural areas that are difficult to connect to the central power grid can instead set up a microgrid to serve their needs.

What drawbacks should businesses be wary of?

While microgrids are an elegant solution to the world’s current power problems, they are not without their own set of difficulties.

Because microgrids do not use their own energy source continuously, they necessitate additional storage space and equipment.

Despite the development of intelligent microgrids, resynchronization with the main grid is not always smooth.

Local utility companies and governments have yet to develop consistent microgrid legislation and protocols.

Because microgrids serve local communities, they collect sensitive personal data that could be compromised by malicious actors. Furthermore, new cybersecurity regulatory laws have made microgrid adoption more difficult and costly.

Microgrids represent a paradigm shift, moving away from centralized distribution and toward a decentralized network of smaller supply stations. It empowers communities to become more energy resilient and dynamic. Furthermore, low generation and distribution costs, off-loading capability, cleaner energy production, and stable supply have made microgrids a viable power supply option.

Learn more about the latest technology trends driving the energy sector by visiting Voltreum, a forward-thinking blockchain-based technology company.

 

For more information:

Website: https://voltreum.com/

Telegram: https://t.me/voltreum_official

Twitter: https://twitter.com/voltreum

linkedin: https://www.linkedin.com/company/voltreum/

 

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