Smart Grid Solutions: Top 5 Technologies for Efficient Energy Management

There is a lot of confusion when it comes to discussing smart grid solutions. Most people are aware of the term "grid", which refers to an electric grid, and assume that a smart grid and an electric grid are the same thing. In reality, there are some crucial differences between the two, which are linked to the natural evolution of electric grids over time to meet the current needs of customers.

Ultimately, the first electric grid appeared at the end of the 19th century. Nowadays, the world counts over 9,200 grids, which are responsible for delivering approximately 1 million Megawatt power to a variety of consumers. So what is a smart grid, and what do you need to know to build an effective smart grid solution?

What is a Smart Grid and How Does It Work?

A smart grid is a type of energy management system (EMS) that regulates how electricity is produced, distributed, and stored inside a connected system. The introduction of smart grid technology is an extension of analog grid technology that allows for two-way communication to control the operation of appliances. In simple words, a smart grid is an electric grid with the addition of components that enable power flow monitoring between the points of electricity generation and the points where it reaches the consumers, and power flow control in order to match real-time needs:

• Automation
• Communication
• IT systems

Smart Grid vs. Traditional Electric Grid

The smart grid has a proactive response that ensures that power flow mishaps and problems can be addressed in real-time without the need for external notifications. By relying on digital technology for monitoring, control, and response, the smart grid establishes a direct link between the utilities and the consumers.

Core Technologies That Make a Grid Smart

The United States Department of Energy describes 4 specific types of technology advances to help transition electric grids into smart grid solutions:

• Technology including sensors for accurate measurements
• Management panel technology with decision support software and mechanism
• Automatic control targeting power distribution, faults and repairs
• Two-way communication between the electric grid components that is fully integrated and automated

To increase efficiency, lower energy consumption and costs, and increase the transparency and dependability of the energy supply chain, this smart grid system enables monitoring, analysis, control, and communication throughout the supply chain. By utilizing smart net meters, the smart grid was created with the intention of addressing the shortcomings of traditional electric grids.

Main Features and Functions of Smart Grid Solution

Smart grid solutions come with many features that don't just benefit the electricity provider but also the consumers.

• Monitoring in real time
• Automated management for outage and fast power restoration
• Enhanced energy management
• Energy usage that can be tracked and managed
• Opportunities to decrease and conserve electricity consumption
• In-house displays for effective tracking
• Smart and automated tracking and overview through web portals and mobile apps
• Incentivizing consumers to change energy usage to keep costs low
• Dynamic pricing mechanism
• Better integration for renewable energy generation

It is worth noting that the Environmental and Energy Study Institute (EESI) recognized as early as 2009 the pivotal role of smart grid technology in the creation of an energy-efficient power network. A smart grid solution is a critical foundation for the implementation of renewable energy systems into the electric grid. Indeed, as renewable energy sources such as solar energy and wind power are variable, the need for a demand-responsive grid that can make the most of the energy available efficiently is vital.

Benefits of Smart Grid Solutions for Energy Efficiency

It makes sense to transition from a traditional electric grid to smart grid solutions that are better equipped to tackle the challenges of modern energy consumption:

Key Benefits:

• Efficient transition and distribution of electric power
• Reducing costs for consumers but also operations, maintenance, and management
• Lowering electric power tariff and rates as a result of reducing peak demand
• Reducing peak demand
• Providing quick recovery after disturbances in feeders and lines
• Full integration with renewable energy sources
• Large scale load sharing and load reduction

Challenges in Building a Reliable Smart Grid System

Smart grid solutions can effectively target some of the main complaints about electric grids, namely the high costs, lack of responsiveness in the event of power shortage, and the high environmental impact. However, the integration of digital technology into the electric grid creates a new range of challenges:

Improving Grid Reliability with Smart Technologies

It's more crucial than ever to keep the smart grid stable. Grid operators must take every precaution to prevent disruptions because the patterns of electricity consumption are changing rapidly in these difficult times. Identifying, isolating, and removing problems while rerouting power to avoid hurting as many end users as possible can only be achieved with strategic fault management and effective FLISR technology (Fault Location, Isolation, and Service Restoration).

Enhancing Grid Efficiency and Performance

Technical losses are becoming a significant threat for smart grid solutions. These losses are frequently linked to a number of causes, including:

• Extensive distribution networks
• Distribution lines' conductors that are too small
• Line overloading
• Distribution transformers installed too far away from load centers
• Low power factor across the distribution system
• Feeder phase current that is not balanced
• Improper transformer sizing and selection

Cybersecurity Risks in Smart Grid Systems

The energy sector is becoming more digitalized, but this has drawbacks as well. There have already been instances where a group of hackers compromised energy firms' systems and caused a controlled blackout to affect thousands of homes.

Practical Applications and Use Cases of Smart Grid Systems

Smart grid solutions can be applied at a whole community level or in smaller environments, such as creating a micro smart grid to cover a temporary event. Yet, regardless of their sizes, smart grid solutions can be used in a variety of application purposes:

1. Sustainability focus: Utilizing a smart grid solution to integrate further with renewable energy sources and build a carbon-neutral future.
2. Resilience against natural disasters: Utilizing smart grid solutions in regions that are prone to extreme weather such as storms to reduce power outage and drives self-repairing features.
3. Scalability to growing needs and households: Relying on smart grid technologies to meet the growing and varied needs of consumers in crowded areas.
4. Protection against terrorist attacks: Cutting down the power can take a whole region down. But in a smart grid environment, FLISR technology and micro grid setups can provide fast restoration.
5. Cost reduction policy: Smart grid solutions offer the perfect response to the constant increase of energy costs, making costs more manageable for consumers.