What exactly is Distributed Generation?
The United States Environmental Protection Agency (EPA) defines distributed generation as an approach that uses multiple methods rather than just one technology.
Society has become all but reliant upon electrical energy in order to provide citizens with a host of vital services. From heating and cooling to communications and food storage, the world would quickly enter into a new "dark age" if this type of on-demand energy suddenly failed. However, other concerns such as efficiency and the ability to adopt environmentally friendly methods are just as important. This is why an approach known as distributed generation has become extremely popular.
What is distributed generation in regard to electrical energy systems? How is this type of power generation planned and implemented? What are the specific benefits of distributed generation and are there possible disadvantages? Are there any cutting-edge technologies that are set to further transform this sector? These are a handful of the questions that this article will tackle.
The United States Environmental Protection Agency (EPA) defined distributed generation as an approach to producing electricity that relies upon several methods as opposed to a single technique. The main intention is to provide a reliable source of power while minimising the impact of these systems upon the environment.[1]
While traditional techniques such as the use of coal-burning plants to produce electricity are still utilised, distributed generation has become increasingly reliant on alternative sources of power. The main intention here is to reduce the use of fossil fuels while still being capable of providing customers with energy on demand. It is thought that "green" technologies will feature even more prominently within the distributed generation sector in the coming years.[2]
One of the core strengths associated with distributed generation involves the numerous potential resources which can be used to produce power. So, what options are available? The answer to this question is partially based on whether we are referring to the residential or commercial sector. Here are some of the ways that clean electricity can be produced when dealing with a residential market:[1]
In the event that a company (or conglomerate of companies) employs distributed generation systems for commercial consumption, the types of electricity options often tend to increase:[3]
Note here that these distributed generation methods may or may not be used in synergy with other techniques such as fossil fuels or even nuclear power.
The fundamental principles behind a distributed generation system are not altogether different when compared to those which rely upon a single source of power. The first step involves producing the power itself via one or more of the techniques outlined in the previous section. Whether referring to solar energy or the use of biomass fuels, the electricity plant will feed this power into an electricity grid (commonly referred to as a "grid").
It is also interesting to note that a distributed energy system (DES) will often work in conjunction with more traditional methods. For instance, one common approach involves proactively monitoring peak demand times. These are some of the instances when a traditional power grid may have difficulty keeping up with primary energy consumption requirements. In such cases, distributed generation systems will provide an alternative source of on-demand power.[4]
The ability to provide electric power has taken on a decidedly "intelligent" approach in terms of distributed generation. After all, it is extremely important to gauge ongoing energy consumption in order to appreciate how commercial or residential systems are functioning as a whole. In the past, this was primarily accomplished through the use of standard electric meters that would employ the kilowatt hour as a means to monitor consumption levels. However, the presence of smart meters is now becoming commonplace when used in synergy with distributed generation. This approach offers several advantages including:[5]
It is also thought that smart technology will help to promote green power, as more efficient energy consumption may reduce the need to construct additional distributed generation plants.
Planning any type of distributed generation grid is arguably one of the most important phases, as it will ultimately determine the types of systems that need to be implemented. The first step involves analysing peak load times in order to better appreciate when additional power may be required. This is then measured against the capacity of existing electrical substations. The ratio itself is referred to as a "load profile".[6]
Once this data has been interpreted, it is next important to research what types of distributed generation options are available. Many variables will be taken into account including the location, access to renewable resources and the overall cost of implementation. For example, areas with few geographic obstacles could employ wind generation while those found close to a major river might instead leverage electricity generation through a series of hydroelectric turbines.
It should be noted that this is a rather basic description of how the distributed generation of power is analysed. There may be other factors to address such as project feasibility, long-term costs and public opposition to the location of the installations themselves.
It is still important to adopt a more objective approach to appreciate the pros and cons of distributed generation. Here are some of the primary advantages:[7]
Still, a handful of drawbacks must be noted:[8]
What is the future of distributed generation? One major advancement in regard to the future of distributed generation comes in the form of the rather humble fuel cell. The typical hydrogen fuel cell offers a clean source of on-demand power; particularly in the event of a system fault or a partial grid failure.[9] Direct methanol fuel cells (DMFC) technology is yet another option. In this case, primary benefits include low storage costs, safer refuelling techniques and the sheer abundance of methanol itself.[10] It is now clear to see what distributed generation has generated such interest in recent times. As the technologies associated with these techniques continue to make advancements, consumers should be able to leverage the benefits associated with such clean and reliable sources of power.
The United States Environmental Protection Agency (EPA) defines distributed generation as an approach that uses multiple methods rather than just one technology.
Smart meters have become commonplace in conjunction with distributed generation. This approach offers several advantages, including:
Distributed power generation has the following advantages:
Sources
[1] https://www.epa.gov/energy/distributed-generation-electricity-and-its-environmental-impacts
[2] https://en.wikipedia.org/wiki/Distributed_generation
[3] https://www.cummins.com/news/2021/11/04/what-are-distributed-energy-resources-and-how-do-they-work
[4] https://inbuildingtech.com/energy/distributed-energy-systems
[5] https://www.cpuc.ca.gov/industries-and-topics/electrical-energy/infrastructure/the-benefits-of-smart-meters
[6] https://www.researchgate.net/figure/Distribution-system-planning-explanation-a-traditional-distribution-network-planning_fig1_327338382
[7] https://www.americasgenerators.com/blog/post/2019/11/12/pros-and-cons-of-distributed-generation.aspx
[8] https://www.ipl.org/essay/Advantages-And-Disadvantages-Of-Distributed-Generation-PKNJ4X74AJF6
[9] https://www.hydrogen.energy.gov/fuel_cells.html
[10] https://www.sciencedirect.com/topics/chemical-engineering/direct-methanol-fuel-cell