Microgrid Solutions

Why do you need microgrid solutions

As power demands continue to rise, and energy availability and reliability become a primary focus, utilities, commercial and industrial companies are seeking microgrid solutions to ensure they have a reliable, resilient, secure, and economical supply of electricity.

A roof of a building installed with solar panels

Reliability
Resilience
Security
Sufficiency

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Microgrids improve reliability

Microgrid is designed to provide uninterrupted, 24/7 power and to balance load demands and load management for an organization with changing power needs.

Microgrids support resilience

Microgrid provides stability for mission-critical structures such as hospitals in severe weather conditions because they are not dependent on traditional electric grids.

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Microgrids enhance grid security

The distributed generation and smaller sizes make the microgrid more secure from both physical and cyber threats.

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Microgrids boost
sufficiency

By adopting microgrid technologies, the utility can forecast and optimize power usage based on real-time statistics, which reduces overall operational costs and CO2 emissions.

Reliable
Resilient
Secure
Sufficient

Reliable

Microgrids are designed to provide uninterrupted, 24/7 power and to balance load demands for an organization with changing power needs.

Resilient

Microgrids provide stability for mission-critical structures such as hospitals in severe weather conditions because they are not dependent on traditional grids.

Secure

The distributed generation and smaller sizes make microgrids more secure from both physical and cyber threats.

Sufficient

The utility can forecast and optimize power usage based on real-time statistics and demands, which reduces overall operational cost and carbon-dioxide emissions.

How does a microgrid work

A microgrid co-locates electricity generation and consumption. Unlike the traditional utility grid, which generates electricity in a centralized power plant and delivers it through a series of substations and hundreds of miles of transmission lines, a microgrid network generates electricity on-site.

The utility grid

Microgrid is an interconnected system for our everyday power demands

Electricity is generated at central power plants and transported over long distances. Buildings and municipalities connect to this power through a series of substations and transmission lines. With the limited paths for energy to be delivered, thousands of users can be left without power if one part of the electric grid fails or needs to be repaired during the event of a natural disaster or cyber threat.

In contrast, a microgrid can operate autonomously (in "island mode") using local energy sources to generate power for individual buildings or a campus of buildings.

The microgrid

Microgrid generates electricity on-site with distributed energy resources (DERs) and loads

By using backup diesel generators and distributed renewables, a microgrid can incorporate battery systems to store and deploy electricity during outages or peak demands.

Types of microgrid

Off-grid/remote - always operate in island mode due to a lack of electrical infrastructure from the utility grid.
Grid-connected - a group of interconnected customer loads and distributed energy resources within clearly defined electrical boundaries.
Networked/nested - consist of separate distributed energy resources that are connected to the same utility electric grid circuit segment.

Microgrid Controller

An intelligent grid management software for the daily operation of microgrid

The self-contained microgrid is managed by a grid management software that automatically switches the facility between the utility grid and the microgrid based on factors such as power reliability and cost efficiency.

Corinex GridValue provides customized provisioning, management, and near real-time visibility within one single platform, allowing energy distributors to connect, monitor, and control all DERs and optimize operational performance.

The utility grid

An interconnected system for our everyday power demands

Electricity is generated at central power plants and transported over long distances. Buildings and municipalities connect to this power through a series of substations and transmission lines. With the limited paths for energy to be delivered, thousands of users can be left without power if one part of the grid fails or needs to be repaired during the event of a natural disaster or cyber threat.

In contrast, microgrids can operate autonomously (in "island mode") using local energy sources to generate power for individual buildings or a campus of buildings.

The microgrids

Generating electricity on-site with Distributed Energy Resources (DERs) and loads

By using backup diesel generators and distributed renewables, microgrids can incorporate battery systems to store and deploy electricity during outages or peak demands.

Types of microgrids

Off-grid/remote - always operate in island mode due to a lack of electrical infrastructure from the utility grid.
Grid-connected - a group of interconnected customer loads and distributed energy resources within clearly defined electrical boundaries.
Networked/nested - consist of separate distributed energy resources that are connected to the same utility grid circuit segment.

Microgrid Controller

Intelligent system managing the daily operation of microgrids

The self-contained microgrid is managed by intelligent software that automatically switches the facility between the utility grid and the microgrid based on factors such as power reliability and cost efficiency.

Corinex GridValue energy management system provides customized provisioning, management, and near real-time visibility within one single platform, allowing energy distributors to connect, monitor, and control all DERs and optimize operational performance.