When I first started working in the power industry 40 years ago, we didn’t have portable computers or cell phones, and the only electric vehicle I ever thought I would see was a golf cart. Thanks to advancements in technology and an increased focus on sustainability, the energy landscape is changing dramatically, and the continued electrification of almost everything is the future!

According to the U.S. Department of Energy Solar Futures Study, we could see a 50% increase in electric power generation by 2050. In addition to increased demand, utilities are facing a powerful confluence of architectural, technological, and socio-economic difficulties. These challenges include the need to integrate utility-distributed renewable energy systems, severe weather events, aging infrastructure, growing cybersecurity demands due to investments in digital transformation, and the global effort to reduce greenhouse gas emissions.

Increasingly, utilities are turning to distributed generation to address these challenges.  While conventional power stations are centralized and often require electric energy to be transmitted over long distances, distributed generation employs decentralized, modular, and more flexible technologies―often including renewable energy―located near the loads they serve. These systems often encompass multiple generation and storage components, referred to as hybrid microgrids.

According to the American Petroleum Institute, the use of renewable energy with natural gas as a bridging fuel is an effective way to a lower-carbon power sector, and in turn lower energy-related emissions. Plenty of renewable energy sources, including solar and wind, emit no greenhouse gases, however, they are not currently positioned to fully meet capacity or reliability needs of most utilities. Natural gas offers the U.S. power sector a lower-carbon alternative to coal or diesel with the potential to deliver reductions in carbon dioxide emissions.

The appeal of combining distributed renewable energy and natural gas goes beyond potential greenhouse gas emission reductions; this approach also increases energy security and reliability, contributing to economic growth and energy independence. Renewable energy sources alone are intermittent and non-dispatchable. A significant switch to large-scale centralized renewable energy sources also requires investment in transmission, distribution, and other supporting generation and storage technologies.

Distributed generation helps electric utilities deal with the challenges of supply/demand imbalance, reliability, power quality, and infrastructure cost. Among many benefits, small power-generating sources located near points of use help offset investments in centralized power plants, transmission lines, and substations.

In recent years, generator sets fueled by natural gas have proven highly suitable for distributed generation. They are extremely reliable, economical to install and operate, and relatively easy to site and permit. In addition, advances in control technology allow for fast ramping of these units, positioning them to accept loads in a matter of seconds and respond to load swings more rapidly.

Small-scale generation assets are becoming even more valuable as distributed energy resource management systems (DERMS) are being deployed to use them cost-effectively. Additionally, as lower-carbon intensity fuels such as renewable natural gas (RNG), biogas, and hydrogen become more cost effective and readily available, distributed generation equipment can be modified to accommodate these fuels.

Our electric power system faces many challenges, and as the energy landscape evolves to address increased electrification, we will have even greater demand than ever before. Caterpillar is positioned to serve as a trusted partner with the technologies and expertise to provide alternatives to established energy sources and products that utilize fuels that are reliable and cost effective.

For more information on Caterpillar’s innovative power solutions, visit https://www.cat.com/sustainablepower.