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This book focuses on the ways in which military installations and small cities can implement and integrate triple net planning and energy, water, and waste sustainability strategies into broad installation operational management, arrive at the best decision, create policy and communicate effectively to stakeholders. It explores current and emerging technologies, methods, and frameworks for energy conservation, efficiency, and renewable energy within the context of triple net zero implementation practice. Recognizing that the challenge extends beyond finding technological solutions to achieve triple net zero outcomes, the contributions also address the need for a systemic view in the planning phase, as well as adequate communication and policy measures and incentives.
The design, construction, operation, and retrofit of buildings is evolving in response to ever-increasing knowledge about the impact of indoor environments on people and the impact of buildings on the environment. Research has shown that the quality of indoor environments can affect the health, safety, and productivity of the people who occupy them. Buildings are also resource intensive, accounting for 40 percent of primary energy use in the United States, 12 percent of water consumption, and 60 percent of all non-industrial waste. The processes for producing electricity at power plants and delivering it for use in buildings account for 40 percent of U.S. greenhouse gas emissions. The U.S. federal government manages approximately 429,000 buildings of many types with a total square footage of 3.34 billion worldwide, of which about 80 percent is owned space. More than 30 individual departments and agencies are responsible for managing these buildings. The characteristics of each agency's portfolio of facilities are determined by its mission and its programs. In 2010, GSA's Office of Federal High-Performance Green Buildings asked the National Academies to appoint an ad hoc committee of experts to conduct a public workshop and prepare a report that identified strategies and approaches for achieving a range of objectives associated with high-performance green federal buildings. Achieving High-Performance Federal Facilities identifies examples of important initiatives taking place and available resources. The report explores how these examples could be used to help make sustainability the preferred choice at all levels of decision making. Achieving High-Performance Federal Facilities can serve as a valuable guide federal agencies with differing missions, types of facilities, and operating procedures.
Access to reliable and affordable energy, water, and services is an important determinant of the prosperity of cities along with effective mission sustainment at military installations. The idea for this book was conceived at the NATO Advanced Research Workshop (ARW) in June 2012 in Hella, Iceland. The workshop was attended by 50 scientists, engineers, and policymakers representing 15 different nations and multiple fields of expertise, reflecting the global and interdisciplinary nature of climate change and sustainability research. The focus of the workshop was on ways in which military installations and small cities can integrate energy, water, and infrastructure sustainability strategies into city and installation management plans that account for climate change uncertainties. The organization of the book reflects major topic sessions and discussions during the workshop.
Best practices from around the world have proven that holistic Energy Master Planning can be the key to identifying cost-effective solutions for energy systems that depend on climate zone, density of energy users, and local resources. Energy Master Planning can be applied to various scales of communities, e.g., to a group of buildings, a campus, a city, a region, or even an entire nation. Although the integration of the energy master planning into the community master planning process may be a challenging task, it also provides significant opportunities to support energy efficiency and community resilience by increasing budgets for investments derived from energy savings, by providing more resilient and cost-effective systems, by increasing comfort and quality of life, and by stimulating local production, which boosts local economies. The Guide is designed to provide a valuable information resource for those involved in community planning: energy systems engineers, architects, energy managers, and building operators. Specifically, this Guide was developed to support the application of the Energy Master Planning process through the lens of best practices and lessons learned from case studies from around the globe. The Guide introduces concepts and metrics for energy system resilience methodologies, and discusses business and financial models for Energy Master Plans implementation. This information can help planners to establish objectives and constraints for energy planning and to select and apply available technologies and energy system architectures applicable to their diverse local energy supply and demand situations. This Guide is a result of research conducted under the International Energy Agency (IEA) Energy in Buildings and Communities (EBC) Program Annex 73 and the US Department of Defense Environmental Security Technology Certification Program (ESTCP) project EW18-5281 to support the planning of Low Energy Resilient Public Communities process that is easy to understand and execute.
Targeting Net Zero Energy for Military Installations in Kaneohe Bay, Hawaii. A net zero energy installation (NZEI) is one that produces as much energy from on-site renewable sources as it consumes. NZEI assessment provides a systematic approach to energy projects.
This book is written as a practical guide to those interested in the pursuit of energy resilience at a local scale. Energy resilience is defined as the relative ability of an institution to carry out its mission during a shock to the energy system and approach the concept on the level of a single site occupied by a single community or institution. Examples are drawn from four key community types: military bases, healthcare campuses, educational campuses, and municipal governments. The book then describes a framework for developing an energy resilience plan that applies to each. While the focus is clearly on the United States, understanding the energy resilience threat and conducting long-range energy resilience planning will benefit communities all over the globe. Divided into three main parts, Part One describes the specific energy security threats that are facing local institutions and communities and how an energy shock can affect the mission at each of the four community types and the advantages that each will enjoy in their pursuit of energy resilience. Part Two provides concrete guidance for pursuing energy resilience at a particular institution and allows managers to assess where their institution lies on the energy resilience spectrum and plot a course toward where they would like to be. Part Three describes the three main areas of energy resilience performance: energy efficiency, on-site generation, and emergency planning. Case studies are also provided.
This book focuses on the ways in which military installations and small cities can implement and integrate triple net planning and energy, water, and waste sustainability strategies into broad installation operational management, arrive at the best decision, create policy and communicate effectively to stakeholders. It explores current and emerging technologies, methods, and frameworks for energy conservation, efficiency, and renewable energy within the context of triple net zero implementation practice. Recognizing that the challenge extends beyond finding technological solutions to achieve triple net zero outcomes, the contributions also address the need for a systemic view in the planning phase, as well as adequate communication and policy measures and incentives.
This book takes a very close look at energy and energy security from a hands-on, technical point of view with an ultimate goal of sorting out and explaining the deep meaning of energy as well as the key factors and variables of our energy security. The book reviews the major energy sources—coal, crude oil, natural gas, the renewables, and other alternative fuels and technologies—according to the way they affect our energy security now and what consequences might be expected in the future. Topics include the different technical, logistics, regulatory, social, political, and financial aspects of modern energy products and technologies. The advantages and disadvantages of the different fuels, technologies, energy strategies, regulations, and policies are reviewed in detail, sorted, and clearly laid out as well as their effects on our present and future energy security in a way that is easy to understand by high school students, engineers, and professors alike. This book is a must-read for energy executives, environmental specialists, investors, bankers, lawyers, regulators, politicians, and anyone involved, or interested, in today’s energy production and use and their effects on our energy security.
Ending the fossil fuel industry is the only credible path for climate policy Around the world, countries and companies are setting net-zero carbon emissions targets. But what will it mean if those targets are achieved? One possibility is that fossil fuel companies will continue to produce billions of tons of atmospheric CO2 while relying on a symbiotic industry to scrub the air clean. Focusing on emissions draws our attention away from the real problem: the point of production. The fossil fuel industry must come to an end but will not depart willingly; governments must intervene. By embracing a politics of rural-urban coalitions and platform governance, climate advocates can build the political power needed to nationalize the fossil fuel industry and use its resources to draw carbon out of the atmosphere.