Amory Lovins (Rocky Mountain Institute Co-founder) – Integrative Design for Radical Energy Efficiency (May 2019)
Chapters
Abstract
Radical Efficiency in Energy Design: Unlocking Potential Through Integrative Approaches
Abstract:
This article explores the innovative work of Amory Lovins in designing radically efficient energy systems. By combining various concepts from designing a passive solar house to retrofitting industrial systems, Lovins demonstrates the vast potential of integrative design in enhancing energy efficiency. The discussion extends to the design of lightweight vehicles, industrial retrofits, and the implications of these approaches for policy and practical implementation. The article concludes with the success story of a cheap passive house, underscoring the real-world impact and potential of these energy-efficient designs.
Unleashing Energy Efficiency: A Holistic Approach
Amory Lovins, a visionary in energy efficiency, emphasizes the need for a holistic approach to designing systems, whether buildings, vehicles, or industrial processes. His work challenges conventional engineering practices, showcasing how integrative design can unlock significant energy savings and resource conservation. Principles of Integrative Design include employing orthodox engineering principles but asking different design questions in a different order, leading to more efficient and cost-effective solutions. Current energy usage is only about 11% efficient compared to what physics allows, and 85% of energy demand could be avoided using existing knowledge and technologies.
The Passive Solar House: A Model of Efficiency
Lovins’ own house in Aspen serves as a benchmark, achieving 99% passive solar heating with minimal active intervention. This house, with its super insulation, heat recovery systems, and super windows, epitomizes the potential of energy-efficient design in everyday living spaces.
The Power of Integrative Design
In industrial and commercial settings, integrative design has proven its worth. The Empire State Building retrofit and similar projects in India and the U.S. demonstrate how energy savings of up to 80% can be achieved with lower construction costs and improved comfort, all thanks to a holistic design perspective. Energy efficiency reserves are much larger than typically recognized and captured, as integrative design can unlock significant savings. Unlike finite mineral resources, energy efficiency resources are infinitely expandable and deplete only stupidity. New energy efficiency reserves often cost less than existing ones because they involve fewer and simpler widgets used more artfully.
Rethinking Automobile Efficiency
In the field of automobiles, Lovins underscores the importance of reducing tractive load over merely improving powertrain efficiency. The use of advanced materials, like carbon fiber composites, has led to the creation of vehicles that are 70% lighter than traditional steel vehicles, significantly boosting energy efficiency. Only 6% of fuel energy accelerates a car, with most losses due to air resistance, tire friction, and road heating. Reducing tractive load is more effective than improving the powertrain in terms of energy savings. Integrative design involves reducing mass, improving powertrain efficiency, and optimizing the vehicle’s structure.
The Continuous Process of Vehicle Design Improvement
This journey towards more efficient vehicles is iterative, involving continuous design and optimization. Toyota’s adoption of this approach led to the 70% lighter 1X vehicle, designed for the future rather than the past. Companies like Honda, BMW, and others are rapidly surpassing official forecasts for vehicle efficiency.
Industrial Retrofits: A Treasure Trove of Savings
In industrial settings, simple design changes like larger pipes and smaller pumps can lead to substantial energy savings. Lovins’ work reveals that industrial retrofits can reduce energy consumption by 30% to 60%, with new builds achieving even greater savings of up to 90% with lower capital costs. The key is rethinking industrial processes and redesigning basic elements like pumps, fans, and motor systems.
The Case of Data Centers
Data centers offer another opportunity for energy efficiency. Lovins proposes improvements in code optimization, server efficiency, and resource utilization to significantly reduce the energy footprint of these data centers. Two-thirds of the fuel fed into a power plant is lost in the plant and grid. Half the metered electricity is lost in the cooling system and uninterruptible power supplies. Half the server energy is lost due to inefficient power supplies and excessive cooling. Severe underutilization of computing resources and bloatware further contribute to energy waste.
The Impact of Integrative Design
Integrative design is not just a concept but a practical approach with far-reaching implications. It has the potential to triple U.S. energy efficiency and quintuple renewables by 2050, leading to significant cost savings and carbon emissions reductions. To achieve radical energy efficiency, we must embrace a beginner’s mind and shed assumptions and preconceptions, allowing for more creative and innovative solutions. Paul McCready’s example of connecting nine dots with just three lines illustrates the power of thinking outside the box and finding elegant, frugal solutions.
The Passive House Phenomenon
The real-world impact of these concepts is best illustrated by Declan Mulhall’s passive house in Scranton. With its minimal moving parts and efficient design, the house maintains a remarkably low electricity bill, averaging around $100 per month, covering heating, water heating, and appliances. Initially, the utility company mistakenly replaced the meter, believing there was an error. The local newspaper featured the project, attracting significant attention and letters to the editor expressing skepticism in the passive house concept. Amory Lovins praised the passive house approach, emphasizing the potential for further improvements in the electric component. He mentioned the importance of handling ventilation loads and allowing for visitors’ presence, particularly economists, who may generate less body heat. The World Bank retrofit project encountered an issue with infrared sensors failing to detect economists, leading to the employment of ultrasonic sensors to address this problem.
A Sustainable and Prosperous Future
The adoption of integrative design principles in energy systems offers a pathway to a more sustainable and prosperous future. By rethinking conventional design approaches and leveraging the untapped potential of integrative design, significant strides can be made in global energy transformation, benefiting both the environment and the economy.
Notes by: BraveBaryon